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1
The Long and Winding Road…
An Independent Evaluation of the Implementation and
Adoption of the National Health Service Care Record s
Service (NHS CRS) in Secondary Care in England
Final report for NHS Connecting for Health Evaluati on Programme
Kathrin Cresswell, Maryam Ali, Anthony Avery, Nicho las Barber, Tony
Cornford, Sarah Crowe, Bernard Fernando, Ann Jackli n, Yogini Jani, Ela
Klecun, Valentina Lichtner, Kate Marsden, Zoe Morri son, James Paton, Dimitra
Petrakaki, Robin Prescott, Casey Quinn, Ann Roberts on, Amirhossein Takian,
Katerina Voutsina, Justin Waring and Aziz Sheikh
March 2011
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List of authors and contact details
Dr Maryam Ali, Research Fellow, Department of Management, London School of Economics
& Political Science; Visiting Lecturer, Simon Fraser University, BC, Canada
Professor Anthony Avery, Professor of Primary Healthcare, Division of Primary Care, The
University of Nottingham
Professor Nicholas Barber, Professor of the Practice of Pharmacy, Department of Practice
and Policy, The School of Pharmacy, University of London
Dr Tony Cornford, Senior Lecturer in Information Systems, Department of Management,
London School of Economics & Political Science
Kathrin Cresswell, Research Associate, eHealth Research Group, Centre for Population
Health Sciences, The University of Edinburgh
Dr Sarah Crowe, Research Fellow, Division of Primary Care, The University of Nottingham
Dr Bernard Fernando, Honorary Clinical Research Fellow, eHealth Research Group, Centre
for Population Health Sciences, The University of Edinburgh
Professor Ann Jacklin, Chief Pharmacist Hammersmith Hospitals NHS Trust, Imperial
College Healthcare NHS Trust
Dr Yogini Jani, Research Fellow, Department of Practice and Policy, The School of
Pharmacy, University of London
Dr Ela Klecun, Lecturer in Information Systems, Department of Management, London School
of Economics & Political Science
Dr Valentina Lichtner, Research Officer, Department of Management, London School of
Economics & Political Science
Kate Marsden, Research Associate, Division of Primary Care, The University of Nottingham
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Zoe Morrison, Research Associate, eHealth Research Group, Centre for Population Health
Sciences, The University of Edinburgh
Dr James Paton, Consultant Microbiologist, Burton Hospitals NHS Foundation Trust
Dr Dimitra Petrakaki, Research Officer, Department of Management, London School of
Economics & Political Science
Professor Robin Prescott, Emeritus Professor of Health Technology Assessment, Centre for
Population Health Sciences, The University of Edinburgh
Dr Casey Quinn, Lecturer, Division of Primary Care, The University of Nottingham
Dr Ann Robertson, Research Fellow, eHealth Research Group, Centre for Population Health
Sciences, The University of Edinburgh
Professor Aziz Sheikh, Professor of Primary Care Research and Development, eHealth
Research Group, Centre for Population Health Sciences, The University of Edinburgh
Dr Amirhossein Takian, Research Fellow, Department of Practice and Policy, The School of
Pharmacy, University of London
Dr Katerina Voutsina, Research Fellow, Department of Management, London School of
Economics & Political Science
Dr Justin Waring, Associate Professor in Public Services Management, Business School,
The University of Nottingham
Address for correspondence: Aziz Sheikh, eHealth Research Group, Centre for
Population Health Sciences, The University of Edinburgh, Teviot Place, Edinburgh EH8 9AG
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Foreword
This has been one of the most complex, challenging and politically sensitive evaluations that
we have ever undertaken. The extensive multi-faceted fieldwork conducted in busy clinical
settings was only possible thanks to the support and input of many individuals and
organisations, whose support we are delighted to acknowledge on the following pages. We
would here however particularly like to single out Professor Richard Lilford for having the
foresight to commission this important work, Professor David Bates for his thoughtful
guidance and support throughout, and also our research team who collectively have
engaged with this evaluation with considerable thought, determination and skill. We hope
that the summary of our work presented in the pages that follow will provide important food
for thought on the future implementation plans for the National Health Service Care Records
Service and also for future evaluations of the introduction of major information technology
interventions into health systems.
Aziz Sheikh, Tony Cornford, Nick Barber and Tony Av ery
Edinburgh, London and Nottingham
March 2011
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Acknowledgements
This large scale evaluation would not have been possible without the help of a number of
people who we here take great pleasure in acknowledging. First and foremost, we thank
the participating NHS Trusts and individual participants for their time and support.
Throughout the process of undertaking this work we have had helpful support from
colleagues at the NHS Connecting for Health Evaluation Programme led by Professor
Richard Lilford and supported by Lee Priest, Nathalie Maillard and Jo Foster. Lee kindly
also represented the funders on our Independent Project Steering Committee which,
under the able chairmanship of Professor David Bates, and with the helpful support of
Professor Martin Buxton, Antony Chuter, Ian Cowles, and Kathy Mason, provided
thoughtful and constructive advice throughout, particularly in relation to adapting our
research in the light of the evolving implementation landscape. We are also particularly
grateful to many senior colleagues in NHS Connecting for Health for their time and help
during various stages of this evaluation. Our thanks are also due to Dr Brian Serumaga for
his help with aspects of the analysis. We acknowledge the support of the National Institute
for Health Research, through the Comprehensive Clinical Research Network.
Jillian Hosie, Rosemary Porteous and Anna Wierzoch provided much needed
administrative support; Anna also proof-read the final manuscript. We are furthermore
grateful to the heroic transcribing efforts of Jan Bunyan, Kate Neilson, Linda Pitt and Fiona
Adams. Christine McLeod has provided much needed financial expertise.
We had the welcome opportunity to discuss our research plans and present our interim
findings at our Project Advisory Board meetings, at which we received helpful feedback,
which both helped refine our original research plans and, more recently, our interpretation
of findings. We are pleased therefore to record our gratitude to the members of this Board:
Dr Gifford Batstone, Philip Brown, Lorraine Catwell, June Davis, Professor Dipak Kalra,
Kathy Mason, Yvonne Pettigrew, Lee Priest and Dr Marlene Winfield. Our thanks are also
due to the anonymous peer-reviewers of an earlier draft of this report for their constructive
feedback and suggestions for improvement. To all of these individuals, who so generously
gave us their time, we wish to record our most sincere thanks.
Our interim results and methods have been published in the BMJ and can be accessed
under: http://www.bmj.com/content/341/bmj.c4564.
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Abstract
Background: In 2002, the National Health Service (NHS) in England embarked on a major
technology-based transformation of healthcare. Central to this National Programme for
Information Technology (NPfIT) was the creation of a comprehensive “cradle-to-grave”
electronic health record (EHR) – the NHS Care Records Service (NHS CRS) – that could be
shared across a range of NHS providers for all 50 million residents of England.
Aims: To undertake an evaluation of the implementation and adoption of the NHS CRS in
secondary care sites in England, across the three clusters: North-Midlands and East; South;
and London.
Methods: A mixed methods case study-based longitudinal evaluation undertaken in 12
‘early adopter’ sites across the three geographical implementation clusters. Sites were
opportunistically sampled according to their current or planned stage of implementation, and
to provide a variety with respect to: location, size, type of care provided, Foundation and
teaching status, and NHS CRS software system. Fieldwork was undertaken in six
complimentary work-packages in which we sought to understand how the participating trusts
made the NHS CRS work (or not) in their organisations; to identify local consequences of
implementing the new systems, the costs incurred and to assess whether the new systems
resulted in a reduction in missing information in outpatient clinics.
Main findings: Implementation of the NHS CRS software systems has proceeded much
more slowly and with, as yet, substantially less functionality than was originally planned. The
delays have related, at least in part, to ambitious expectations about: the nature of EHR
systems; the time needed to build, configure and customise the software; the work needed
to ensure that these systems were supporting rather than hindering care provision; and the
training and support needs of end-users. Other factors affecting the rate of implementation
included: the constantly changing milieu of NHS policy and priorities; the different stages of
development of the different NHS CRS systems; and a complex and multilayered
communication process between organisational structures, along with contractual
arrangements which largely excluded NHS providers and were perceived by users as a
major source of frustration that slowed implementation. As a result of commercial and other
sensitivities about cost and consequences of implementation a full economic analysis could
not be undertaken; however we have identified the main cost categories that need to be
considered in the context of implementing complex EHR systems. At one site, in which a
NHS CRS system of limited functionality had been implemented, there was no improvement
in the amount of missing patient information in outpatient clinics. More broadly, however,
there was some evidence that these early experiences of deploying the NHS CRS have
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resulted in important organisational learning and development of relevant competencies
within and amongst NHS Trusts and NHS Connecting for Health (NHS CFH).
Conclusions: This evaluation has found that implementation of the selected NHS CRS
software packages has proved time consuming and challenging, with limited discernible
short-term benefits for clinicians or patients, although we began to see the application of new
approaches to managing information at some sites as systems matured. These findings do
not preclude the possibility of longer-term benefits, which have been achieved in some
hospitals in other countries, but these do often take years to realise. Nonetheless, there
remains considerable buy-in into the vision and potential offered by the NHS CRS. In a
future in which hospitals may have to function as business entities in order to survive, there
is very likely to be a need to capture and quantify many aspects of business processes using
some form of the NHS CRS. The recent move away from a centralised top-down delivery
model to one in which there is greater local autonomy and choice is an overall welcome
development. However, this needs to be accompanied by NHS-wide standards and incentive
setting mechanisms in order to ensure continuing progress both locally and nationally,
towards integrated, joined-up care systems.
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Executive summary
Introduction
1. Health systems globally face common challenges. These result from many sources
and include: increasing population size; demographic transitions and the growth of
older, frailer sections of the population many of whom live with one or more long-term
conditions; the ever-increasing array of new and expensive treatment options; and
increasing public expectations.
2. Against this background, there is rising international interest in the potential of
information technology (IT)-based systems for improving the safety, quality and
efficiency of healthcare. Electronic health records (EHRs) usually represent the
backbone of these service redesign initiatives.
3. Most of the evidence to support such initiatives and on the effectiveness of EHRs
and associated systems originates in small-scale implementations of software
systems that have been extensively customised to suit local needs. Even these
small-scale and often well-resourced implementations are however not without
problems; particularly when care processes are appreciably changed, leading to
restructuring of work and innovation in organisational processes.
4. In the light of the anticipated (but as noted above unproven) benefits associated with
the use of EHRs, international efforts are now focusing on larger scale EHR
initiatives. Issues known to be encountered in small-scale implementations may
however be exacerbated in these more ambitious transformative ventures.
5. England’s National Programme for Information Technology (NPfIT) is such a large
scale EHR implementation attempting to introduce, amongst other things, national
EHRs across NHS specialist care providers throughout England. It has been
distinguished by its (national) scale, centrally driven delivery model and extremely
ambitious timeline. It is one of the few sustained attempts to implement EHRs
nationally in a centralised way.
Aims and objectives
6. We were commissioned by the NHS Connecting for Health Evaluation Programme
(NHS CFHEP) to conduct both a formative and summative evaluation of the
implementation and adoption of the National Health Service Care Records Service
(NHS CRS), and specifically the Detailed Care Record (DCR), in NHS secondary
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care sites across England. In doing so, we were asked to inform the implementation
and adoption of the NHS CRS, and to generate insights to inform future local and
national strategic implementation decisions.
7. During the conduct of this research, some of our aims, objectives and methods had
to be adapted. This was due to a combination of changes in strategic direction of the
implementation, e.g. from top-down phased implementation of nationally procured
systems towards an increasing emphasis on local choice in relation to a range of
systems, and the severe and persistent delays within the Programme. In addition, the
envisaged scope of the chosen software continued to change over the course of the
study period and only limited clinical functionalities were deployed.
8. We were thus not, as anticipated at the time of writing the proposal, in a position to
investigate the implementation and adoption processes, and the worked out
consequences of fully implemented and function-rich NHS CRS software, but instead
had to assess the NHS CRS software in the context of early implementations of often
limited functionality.
9. Despite the challenges we pursued our original research plans as far as possible and
appropriate, seeking to undertake a theoretically grounded, empirical, longitudinal
investigation into the implementation and adoption of the NHS CRS in English
secondary care.
Methods
10. We conducted a mixed-methods real time evaluation of the introduction of the NHS
CRS in secondary care settings during the period September 2008 (with data
collection beginning in February 2009) to January 2011. In doing so, we collected a
broad range of qualitative and quantitative data from 12 ‘early adopter’ Trusts
committed to use one of the three core NHS CRS software systems (i.e. Lorenzo
Regional Care, RiO and Cerner Millennium). We conceptualised each participating
Trust as a case study site to reflect the importance of local contingencies, whilst
attempting to make general inferences transferable to other contexts and facilitate
organisational learning.
11. Our evaluation drew on sociotechnical principles and was informed by Cornford and
colleagues’ evaluation framework.
12. We organised the work into the following six complementary work-packages (WPs)
investigating different dimensions:
o Implementation, deployment and organisational learning (WP1)
o Stakeholder attitudes, expectations, engagement and satisfaction (WP2)
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o Organisational consequences: organisational workflow, professional role and
data quality transformations (WP3)
o Assessment of costs of NHS CRS implementation (WP4)
o Assessing error, safety and quality of care (WP5)
o Organisational consequences and implications for future IT deployments and
evaluations (WP6).
13. The majority of our data collection activity was qualitative in nature, primarily
consisting of interviews with a range of key stakeholders, including local
implementation teams, users, and a range of governmental and commercial
stakeholders. This was complemented by researchers’ field notes as well as
observational and documentary data from Trusts, meetings with governmental
stakeholders, conferences, and national documents.
14. Quantitative data consisted of an assessment of the local costs of implementation
and an assessment of the impact of the new system on the availability and
completeness of outpatient clinical records (WP 4 and 5).
15. We also developed a survey tool to investigate the use and usability of EHRs and
related clinical systems, and the user experience with these, including attitudes and
opinions.
16. Our complete dataset comprised:
o 431 semi-structured interviews
o 590 hours of observations
o 234 sets of notes from observations, researcher field notes and conferences
o 809 documents
o 58 national and regional documents
o 130 questionnaires on users’ use and views of clinical systems
o 4,684 questionnaires on case note availability.
17. Data in individual Trusts were collected by a designated lead researcher who also
took the lead in analysis for their particular case study; regular analysis workshops
with the wider team helped us to validate individual case study findings and to
integrate multiple case studies to draw out more transferable findings.
18. Throughout the study, emerging findings were fed back to individual participating
Trusts, NHS CFH, NHS CFHEP; the feedback received informed subsequent data
collection.
Main findings
The main findings relating to each individual WP are outlined below.
11
Local consequences (WPs 1-3)
19. Implementing new technology-based clinical systems is never a straightforward
activity, particularly when this involves replacing existing systems that are perceived
as functioning well locally. It is hard and takes time, especially in the light of the
complexity of implementing NHS CRS systems within and across Trusts, which will
probably consist of thousands of staff with different requirements and expectations.
Clinical, administrative and technical staff has to learn to work-out the consequences
of such systems day-by-day and continue to make them work for as long as they are
in use. This task should not be underestimated.
20. There was not a common vision or understanding of the intended purpose of the
NHS CRS. Different stakeholders expressed different accounts of its intended
purpose. These ranged from the data-centric (data storage and sharing), to business-
centric (business process change) to policy-centric views (modernisation, shift to
patient focus).
21. A variety of approaches was taken to prepare for implementation and a number of
external and internal factors shaped differences in implementation strategies, the
types of software, and stakeholder expectations. These included concurrent changes
occurring in Trusts (e.g. working to achieve Foundation Trust status), in the NPfIT
and in NHS policies and targets, adding further uncertainties and delays to the
process.
22. Relationships between Trusts, Local Service Providers (LSPs), software suppliers
and NHS CFH, often characterised by commercial relations, often resulted in a lack
of focus on teamwork and productive processes (other positive developments that it
might ensure and how the realisation of these might be facilitated). Instead different
parties often worked in silos attempting to achieve what was in their own best
interest. For example, Trusts often lacked budgetary control, information about
contractual arrangements, the ability to configure the software or engage in direct
communication with the service supplier. This led to a sense of detachment from the
process for Trusts. The communication between customer and developer was often
fragmented, and the potential for intelligent problem solving clashed with the
structured approach characterising software contracts.
23. All Trusts adopting NHS CRS software system faced trade-offs between
standardisation and localisation. Administrative, technical and clinical users
interviewed were often aware of the tensions between standardisation and
localisation and a need to provide a balance reflecting the needs of individual
organisation and the NHS more generally. Assumptions inscribed into NHS CRS
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systems as to how the English NHS operated were often challenged. The complex
supply chains added bottlenecks in resolving such issues and in resolving
configuration and customisation issues.
24. We also found that the NHS CRS was usually portrayed as a set of clinical systems
for primarily clinical users, but the direct users of the software systems we studied
were frequently allied health professionals and administrative staff. Their interests
and concerns, however, seemed less likely to be captured or acted on as
implementations went forward.
25. Technology for EHR has to be “fit for purpose”, with acceptable levels of reliability
and utility in the clinical setting. Yet NHS CRS systems often failed such basic tests,
e.g. presenting usability problems that could become critical, not least in reducing
user commitment to the systems.
26. We found that NHS CRS systems had at times significant influences on users’
professional identity, which in turn impacted on attitudes towards these systems.
27. As expected, the introduction of NHS CRS systems influenced changes in work
practices for a variety of clinical and non-clinical stakeholders. Data entry work was
often redistributed, e.g. from administrative staff to clinicians, from nurses to doctors
and vice versa. Work practices did not become “paperless”: note-taking while with
the patient was still most often done on paper, with data entry in NHS CRS systems
done retrospectively.
28. Enhanced availability of data and data management tools were perceived as benefits
when information was legible, available in “real time”, more easily searchable and
retrievable, and accessible “any time” and “anywhere” by multiple concurrent users.
Electronic transmission of referrals, requests, reports, etc, was reported as making
some workflows faster overall, although individual stages of these workflows could
become more or less time-consuming than the work system that was previously
operational, with a range of consequences for the different staff involved.
29. To make the most of these data sharing and transactional benefits, a critical mass of
users and data were needed. This required time and a continuation of faith in the
system while numbers of users and the volume of data built up; this in turn allowed
data quality issues to be addressed and relevant new practices to become
established.
30. The availability of digital data could facilitate sharing information across teams or
services within a Trust, or even across Trust boundaries. However, designing digital
support for integrated multi-disciplinary clinical pathways was revealed as a complex
process, still only in its infancy.
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31. Our data, drawn from multiple user communities across Trusts, suggests that
significant organisational learning has taken place. At the individual and team level,
within professional groupings and in particular within and across Trusts, the potential
to respect, enhance and benefit from such learning is clear, if not always yet realised.
By taking such a route, real longer-term benefit of the NHS CRS may indeed be
found.
Assessment of costs of NHS CRS implementation (WP4)
32. Total costs varied depending on the system being implemented and the number of
upgrades: higher functionality increased start-up costs, and up-front ‘big-bang’
implementations were larger in scale than the smaller more phased implementations,
with knock-on implications in relation to costs.
33. We developed a cost framework, which successfully captured all the relevant cost
categories for Trusts deploying different systems, different sets of functionality, and
commencing from different starting-points. Using microeconomic production models,
we identified domains of inputs that could be affected by broad-reaching
technological change initiatives such as the introduction of EHRs into secondary care
settings. Financial, planning and other resource-use documents obtained from
hospital Trusts were assessed in order to specify inputs within those domains and
estimate their values.
34. Within the cost framework, infrastructure costs (degree of IT maturity/penetration;
EHR products already on the market; IT hardware budget at the Trust; requirements
of the IT application; and the physical requirements of the operational space) and
personnel costs (data migration; network; testing; training; and support) were the
most significant sources of expenditure. Personnel costs exceeded infrastructure
cost by a factor of two- to three-fold in some sites. This could be because license
costs were borne by NHS CFH. However, it has to be noted that after 2015, these
will be renegotiated and are likely to be borne by Trusts.
35. One of the main outputs of this evaluation is the creation of a Minimum Data Set,
which can be used by Trusts planning to implement the NHS CRS to ensure that they
have a robust costing model. It can also be used as an evaluation tool to collect the
minimum sufficient information (at hospital Trust level) to contribute to future cost-
effectiveness and cost-benefit studies of IT.
36. From the limited cost information obtained at Trust level, ‘early adopters’ reported
that they were exposed to approximately 50% of the overall implementation costs.
However, this exposure varied between Trusts depending on their negotiating
powers.
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Assessing error, safety and quality of care (WP5)
37. We initially undertook a cross-sectional survey in the outpatient departments of four
NHS Trusts to determine the proportion of outpatient encounters for which at least
one, clinically important item of information was missing. The results from an analysis
of 2,897 encounters showed that:
o One in seven patient encounters had at least one item of information missing.
o There were substantial variations in the availability of information across the
sites.
38. We then undertook a before-and-after study in one of these sites that had
implemented an outpatient software module and compared this to a control site that
had yet to implement this module (i.e. a controlled before-and-after study): this
showed that the introduction of the NHS CRS did not result in any reduction in the
proportion of missing information.
Wider contextual considerations and suggestions for future deployments/research (WP6)
39. Contracts between NHS CFH and a limited number of LSPs were seen at the outset
of NPfIT as central to the successful delivery of the NHS CRS – embodying its ethos
of tough contractual negotiations and “ruthless standardisation”, but with regional
variations. However, our research indicated that multiple restrictions imposed by
long-term, central contracts was a significant inhibitor of Trusts’ adoption of the NHS
CRS systems
40. We found scepticism about realising the benefits associated with secondary uses of
data; this is at least in part because it is unclear what will be collected nationally and
how data from different NHS CRS applications might be consolidated.
41. Many stakeholders felt that the press had contributed considerably to a negative
public perception of the Programme as a whole by an unremitting focus on negative
aspects such as delays, costs and problems occurring during implementations.
42. Generally, participants’ accounts were characterised by uncertainty and anxiety
about what would happen to the Programme in the light of the evolving political and
economic landscape.
Conclusions and future research priorities
43. Despite relative successes in some other aspects of the Programme as a whole
(such as the implementations of N3 and the Picture Archiving and Communications
System), the implementation of the NHS CRS in secondary care settings has been
15
considerably more complex and challenging than was originally an ticipated by
many stakeholders.
44. As of December 2010, 8/219 Trusts (4%) were live with limited Lorenzo functionality
in the North Midlands and Eastern (NME) area; in the South 17/45 (38%) Community
and Mental Health Trusts were live with RiO and 9/40 Acute Trusts (23%) were live
with Millennium; and in London 6/32 Acute Trusts (19%) were live with Millennium
software, whilst RiO was being used by 8/10 (80%) Mental Health Trusts and 30/31
Primary Care Trusts (97%). There are, in addition, a number of other software
functionalities being implemented in Trusts, which are not part of the NPfIT.
45. The relatively limited number of secondary care sites where implem entation has
taken place , in combination with the limited ability to share (clinical data in
particular) across care settings , has led many to doubt the overall success of the
Programme. This is because the implementation of EHRs, as part of the NHS CRS,
is usually viewed as the most fundamental transformational element of the NPfIT.
The limited progress to date has been in large part due to the difficulty encountered
integrating relatively inflexible nationally procured software systems int o NHS
organisations in which local needs vary – or are locally perceived to vary – and
where paper-based systems are still seen as an essential part of everyday
organisational functioning.
46. Despite these difficulties, most NHS and other stakeholders remain committed to
the overall vision of shared EHRs ; continuation of such widespread support may,
however, be contingent on offering more opportunity for Trusts and their staff to
contribute to local and national policy development.
47. The top-down and politically driven nature of the Programme has, from its inception,
whilst ensuring necessary high level leadership and support, contributed to a lack of
organisational and user involvement in decision mak ing and, in particular, in
system selection. One consequence has been that two of the three NHS CRS
software systems we studied have had difficulty fulfilling organisational and user
needs in ‘early adopter’ sites. This has had a knock-on effect on professional and
public perceptions of the Programme and led to hesitation amongst other Trusts to
adopt national solutions and adopting Trusts to consider alternatives.
48. Policy makers have already started to shift the focus of efforts to develop and
implement EHRs, set within broader proposed changes to the NHS in England and
reflecting the current economic climate. In developing this policy, and drawing on our
research, we propose the following points:
o The next decade will see many innovations in technology, reforms of public
services and new models for healthcare organisation and delivery. Any
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health informatics policy needs to reflect this dyn amic environment and
be flexible in nature so as to enable the NHS and its different constituent
organisations to respond to evolving needs. For example, the creation of
Foundation Trusts as competing businesses has the potential to reduce the
capacity for learning between Trusts, to the detriment of the NHS as a whole.
o Short-term effort should remain focused on making NHS CRS soft ware
systems work in the sites in which implementation h as already begun .
Sites must be actively supported in charting and taking their next steps which
may or may not be in line with the historic NPfIT strategy.
o Funding for this stream of the Programme needs to be continued for the sake
of the Trusts committed to NHS CRS software systems but, equally important,
in order to retain and build on the substantial and hard won knowledge,
skills and capability that are now available in par ts of the NHS .
o The considerable work by Trusts and NHS CFH in informing the design of the
Lorenzo NHS CRS system should be seen as, at least in part, the intellectual
property of the NHS from which the NHS as a whole should benefit. This work
should not be lost, but will require careful consideration of intellectual
property rights in relation to future developments .
o We advocate a governance structure that will encompass the input of
NHS-wide, public, accountable, bodies (including Monitor and the newly
established NHS Commissioning Board) while giving a primary role to
local NHS organisations in decision-making and impl ementation
strategies . The exact role of this governance structure will need to be
negotiated, but we envisage the role for one or more NHS-wide bodies to
include coordinating and facilitating development of common and open
technical standards (including support for some aspects of software
certification), setting quality benchmarks which Trusts can use (e.g. for
usability and safety), creating incentives for inter- and intra-organisational
learning, liaising with supplier communities, and developing expertise and
drawing together specialists.
o In future policy, whatever the role of central or NHS-wide bodies,
implementation activity needs to be far more locall y owned and driven .
In particular, organisations should not be incentivised to replace existing
systems that are working for them; development of EHR should rather stem
from Trusts’ perceived needs and a well articulated and understood case for
change within the local health economy. This, however, should be in the
context of nationally agreed standards that will allow, in the longer-term, a
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joined up healthcare delivery model and deliver the overall vision
underpinning NHS CRS. We recognise however that this balance is likely to
prove extremely challenging to achieve.
o A consequence of this should be a move away from technology-driven
models of “implementation” (putting computers on trolleys and desks), and
reflect increased attention to Trusts’ operational needs and business
priorities, their work practices, and the potential for beneficial change in work
process. The findings from this evaluation suggest the need to refocus
attention on “adoption”, which should not be seen as a discreet period of
change driven by the arrival of a new technical system, but rather as an on-
going “working-out” of accommodations between staff and technology, and in
which the technology is seen as an enabler of improved care processes,
rather than an end in itself.
o There is also an opportunity to work to align the strategies of the NHS and a
wider variety of commercial software suppliers and service providers. A
stronger and more transparent commercial architectu re could be of great
benefit to all parties, but must not repeat the customer–supplier disjunction of
the NPfIT.
o We expect to see such a market emerge with a larger ra nge of software
systems and service providers and working through s maller contracts .
This market would require providers to demonstrate compliance with agreed
interoperability standards that have been built bot tom-up, but have
achieved a minimum level (benchmark) of usability, clinical safety and
validity as well as service quality measures in relation to pragmatic clinical
practices and business processes; such systems are likely to require less
customisation for individual Trusts.
49. We already have published our interim findings and developed a dissemination
strategy, which will allow a more detailed exploration of the complex issues emerging
from our research. Our main audience here will be national and international health
informatics and information systems perspectives.
50. A range of implications for future research can be drawn from this evaluation. Most
importantly, there is a need for more longitudinal evaluations of IT initia tives to
allow tracking of implementation efforts and organisational responses over periods of
time. Such studies generate insights into how technologies become embedded (or
not) and are made to work in and across organisations. Similarly, detailed studies of
Trusts (and sites in other countries) where EHR systems have become established
and are in everyday use could inform future policy and delivery strategies.
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51. Future studies should also examine the transformative power of EHR in changing (or
not) clinical practices and healthcare professionals’ roles and corresponding
consequences for patients’ experiences, expectations and roles.
52. Research is also needed into the often neglected processes of transition from paper
to electronic records, or from one generation of electronic systems to another. As in
this study, this turns attention to the extended processes of change (changing) and
the ways in which the active users of new systems work-out how to appropriate the
various affordances of any given technology into their work practices and processes
of patient care.
53. A focus on international comparisons in research into technology innovation,
implementation and adoption processes, and overall visions, could help inform future
developments in England. In particular, international experiences could inform the
complex choices and trade-offs faced in EHR impleme ntations between, for
instance: records’ confidentiality and their accessibility; small-scale and large-scale
data sharing; standardisation and interoperability standards. The English context is
distinctive, but this does not mean that important lessons cannot be learned from
studies of other healthcare systems.
54. There is currently a lack of academic and public debate on the long-term
management and maintenance of data recorded in electronic health record systems,
including disposal and security arrangements. The whole lifecycle of electronic
information requires to be considered by policy makers.
55. Future research is also needed on the ethical and legal controversies arising
from research into EHRs , including potential consequences when evaluating
commercial products such as libel suits. Ethical and legal issues are also likely to
become increasingly important in relation to electronically stored data e.g. if patients
are harmed by illegitimate access or misuse of sensitive information.
56. Introducing technologies into healthcare environments clearly requires relationship
building and good lines of communications between suppliers, patients and carers,
clinical and administrative users, Trusts’ managers, professional bodies and
healthcare commissioners. This has so far received limited attention and is an area
that could benefit from specific research and from learning lessons from other
industries.
57. We emphasise that EHR-based innovation in healthcare should not be conceived of
as essentially technically driven (i.e. founded on the inherent properties of EHRs or
any other technology), but should be characterised by new ways of working with
appropriate technologies and seek new ways of delivering better care. Detailed work
process mapping and user centred design combined with exploring options for
19
innovation in the way care is delivered, should be central to future investigations.
Fundamental to this view is the understanding that automation without redesigning
services will simply magnify existing problems.
20
Table of Contents
Acknowledgements ...........................................................................................................5
Abstract.............................................................................................................................6
Executive summary ...........................................................................................................8
Introduction .................................................................................................................... 8
Methods ......................................................................................................................... 9
Main findings................................................................................................................ 10
Conclusions and future research priorities.................................................................... 14
Table of Contents............................................................................................................20
Abbreviations ..................................................................................................................22
Chapter 1: Background....................................................................................................24
1.1 Electronic health record systems............................................................................ 24
1.2 The National Programme for Information Technology ............................................ 30
1.3 The NHS Care Records Service............................................................................. 33
1.4 Evaluating electronic health record systems........................................................... 39
1.5 The structure of this report ..................................................................................... 40
Chapter 2: Aims and over-arching objectives ..................................................................42
2.1 Aims....................................................................................................................... 42
2.2 Objectives .............................................................................................................. 42
Chapter 3: Overview of methodology...............................................................................44
3.1 Introduction ............................................................................................................ 44
3.2 Theoretical background and approach ................................................................... 44
3.3 Sampling ................................................................................................................ 46
3.4 Methods ................................................................................................................. 47
3.5 General methodological considerations.................................................................. 53
3.6 Chapter summary................................................................................................... 54
Chapter 4: Understanding local consequences ...............................................................56
4.1 Introduction ........................................................................................................... 56
4.2 Aims and objectives ............................................................................................... 56
4.3 Methods ................................................................................................................. 57
4.4 Main findings.......................................................................................................... 64
4.5 Conclusions.......................................................................................................... 148
Chapter 5: Assessing and understanding the costs of implementing and adopting the
National Health Service Care Records Service .................................................................158
5.1 Introduction .......................................................................................................... 158
5.2 Aims and objectives ............................................................................................. 160
21
5.3 Methods ............................................................................................................... 161
5.4 Results ................................................................................................................. 169
5.5 Policy implications and recommendations ............................................................ 195
5.6 Future research.................................................................................................... 196
5.7 Discussion............................................................................................................ 196
5.8 Conclusions.......................................................................................................... 200
Chapter 6: Availability of clinically important information in outpatient clinics.................201
6.1 Introduction .......................................................................................................... 201
6.2 Aims and objectives ............................................................................................. 202
6.3 Methods ............................................................................................................... 202
6.4 Results ................................................................................................................. 207
6.5 Discussion............................................................................................................ 216
6.6 Conclusions.......................................................................................................... 219
Chapter 7: Wider contextual considerations and suggestions for future deployments....220
7.1 Introduction .......................................................................................................... 220
7.2 Aims and objectives ............................................................................................. 220
7.3 Methods ............................................................................................................... 221
7.4 Main findings........................................................................................................ 221
7.5 Conclusions.......................................................................................................... 235
Chapter 8: Conclusion, discussion and recommendations for policy and research........236
8.1 Introduction .......................................................................................................... 236
8.2 Summary of main findings: Integration of findings across work-packages ............ 236
8.3 Strengths and limitations of this work ................................................................... 237
8.4 Relating this work to the broader literature ........................................................... 240
8.5 Relating this work to broader IT and policy developments.................................... 241
8.6 Lessons learned and implications......................................................................... 243
8.7 Implications for future research ............................................................................ 248
8.8 Conclusions.......................................................................................................... 249
References....................................................................................................................251
Contributorship..............................................................................................................271
Glossary........................................................................................................................275
Appendices and supporting material..............................................................................289
22
Abbreviations
A&E Accident and Emergency
AHP Allied Health Professional
ASCC Additional Supply Capability and Capacity
ATP Approval to Proceed
BT British Telecom
CCMDA Critical Care Minimum Dataset
CCN Change Control Notice
CDC Clinical Documentation
CEO Chief Executive Officer
CI Confidence Interval
COO Chief Operation Officer
COWs Computers on Wheels
CSC Computer Sciences Corporation
CSE Customer Satisfaction Every time
DBS Database System
DCR Detailed Care Record
DIF Deployment Incentive Fund
DH Department of Health
DVP Deployment Verification Period
EHR Electronic Health Record
EPS Electronic Prescription Service
GP General Practitioner
HDM High level Data Model
ICP Integrated Clinical Pathway
IMP Issue Management Process
iPM iSOFT Patient Manager (interim PAS solution developed by iSOFT)
IT Information technology
LC1 London Configuration 1
LC2 London Configuration 2
LE Lorenzo Enterprises
LEAP Lorenzo Early Adopter Programme
LPfIT London Programme for IT
LSP Local Service Provider
LTC Long-term Condition
MDS Minimum Data Set
23
NHS National Health Service
NHS CFH NHS Connecting for Health
NHS CFHEP NHS Connecting for Health Evaluation Programme
NHS CRS NHS Care Records Service
NLOP National Local Ownership Programme
NME North, Midlands and East (Programme for IT)
NPfIT National Programme for Information Technology
OBS Output Based Specifications
OR Odds Ratio
PAC Public Accounts Committee
PACS Picture Archiving and Communication System
PAS Patient Administration System
PCT Primary Care Trust
PDS Personal Demographics Service
PID Project initiation document
R1 Release 1
R1.9 Release 1.9
R2 Release 2
R3 Release 3
R4 Release 4
RAM Random Access Memory
RBAC Role based access control
RiO CSE Servalec RiO
SCR Summary Care Record
SHA Strategic Health Authority
SIBL Single Instance Board for Lorenzo
SUS Secondary Uses Service
TTO To-Take-Out medication
UCD User Centred Design
VPN Virtual Private Network
WES Warranted Environment Specifications
WP Work-package
24
Chapter 1: Background
Internationally, there is keen interest in implementing modern, digital information
technologies to support the organisation and delivery of healthcare. As one of the first and
most ambitious, nationwide healthcare reforms to be attempted, England’s National
Programme for Information Technology (NPfIT) has attracted particular attention. The
Programme includes the multi-faceted National Health Service Care Records Service (NHS
CRS), which was intended to create a single, “cradle to grave” electronic health record
(EHR) for every NHS patient in England by 2010. This chapter sets the scene for our
research, giving key background information relevant to our evaluation of the implementation
and adoption of NHS CRS software systems in England. It provides an overview of
developments in the NPfIT and of the NHS CRS within it; describes the commissioning
arrangements for the evaluation; considers approaches to evaluating large scale EHR
implementations more widely; and, finally, outlines the structure of the detailed report of our
evaluation which then follows.
1.1 Electronic health record systems
Using computer technology to store and share individuals’ health and healthcare information
is widely viewed as an essential underpinning for safer, high quality and sustainable, modern
healthcare systems. Many countries throughout the world are now seeking to replace paper-
based patient records with life-long, digital records that can be shared across healthcare
organisations and accessed as and when required by all healthcare professionals involved in
a patient’s care. With demographic shifts towards more elderly populations and the
increased prevalence of long-term health conditions, countries in North America, Europe, the
Middle East and Australasia are pursuing EHR implementations in an attempt to address
some of the challenges facing their national healthcare systems.(1;2)
This widespread interest – and in some cases, substantial government investment – in
EHRs reflects the belief that a range of benefits will accrue as a result of implementing these
new systems. In addition to expected economic benefits of modernised service organisation
and care delivery, the theorised benefits of EHRs with clinical alerts and decision support
tools include: greater accuracy and legibility in documenting and communicating patients’
healthcare information; time saving, for example, by avoiding duplicated patient history
taking; reduced clinical errors, and greater safety for patients; no lost records; enhanced
integration of patient care across different times and settings; increased patient satisfaction;
25
improved data quality for clinical audit and research; and the availability of administrative
data for financial and other management purposes (see Box 1.1). EHRs might also provide
patients with more readily accessible information from their own records, and thereby
support patients who seek a more active partnership with healthcare professionals and
enhance self-care.
Aim How? Expected benefits?
1. To improve
patient safety
By providing clinicians
with rapid access to
information about a
patient's:
• Allergies
• Adverse
reactions
• Medications
• Significant
diagnoses and
problems
Clinician benefits
• Immediate access to accurate list of
medications
• Definitive list of allergies and
adverse reactions
• Less time spent piecing together
clinical history
• Reduced risk of error e.g. dosage
and generic/branding confusion
Patient benefits
• Less likely to be harmed
• Assurance that the right information
for diagnosis, treatment and care
planning is available where and
when it is needed
• Corroboration of clinical/medication
history rather than interrogation
Service benefits
• Reduction in hospital admissions
• Reduction in length of stay
• Reduction in litigation costs
2. To improve
access and
responsiveness
by:
By providing key clinical
information (allergies,
adverse reactions,
Clinician benefits
• Improved appropriateness of clinical
care
26
A. Supporting clinical
assessment of
patient's with
urgent and
emergency care
needs
medications and
significant diagnoses and
problems) to:
• Ambulance
service
• Emergency
departments /
Accident and
Emergency
(A&E)
• Walk-in centres
• Minor injuries
units
• Out-of-hours
service
• NHS Direct
• Faster recognition of critical clinical
need
• An end to "flying blind" – access to
medical history for confused or non-
verbalising patients
Patient benefits
• Treated faster, in most convenient
setting
• Care provided closer to home
• No need to repeat clinical history
Service benefits
• Reduction in emergency admissions
• Reduction in A&E attendances
• Speed up decision to treat/admit/
discharge in A&E
• Reduction in face-to-face contacts in
out-of-hours services
• Reduction in ambulances
dispatched
• Reduced emergency journeys to
A&E
B. Supporting
delivery of high
quality care where
patient
communication/
language is a
barrier
By making basic contact
information and key
clinical information
available when people
cannot give e.g. because
of disabilities or first
language other than
English
By recording preferred
language and other care
Clinician benefits
• Knowledge of medical history,
language issues: saves time
• Know which language and
communication aid is needed:
reduces frustration
Patient benefits
• Language/communication needs
27
preferences
instantly known to care
professionals
Service benefits
• Speed up care processes - cost and
time savings from increased
efficiencies
3. To improve
clinical and cost
effectiveness
through
A. Communication of
key data that will
support integrated
planning and
delivery of care
plans across
different providers
of care -
particularly
patients with long-
term conditions
(LTCs)
Availability of key clinical
information across
different healthcare
organisations
Using General
Practitioner (GP)
contribution to include
additional condition
specific information e.g.
conditions, what teams
are looking
after/coordinating care,
what to do in a crisis,
patient preferences
Clinician benefits
• Significant reduction in time and
effort when treating acute
exacerbation of known LTCs
• Minimal disruption to long-term care
when patient seen in unscheduled
environment
Patient benefits
• Experience more joined-up care:
increased confidence in care given
Service benefits
• Reduction in emergency admissions
• Reduction in GP visits
B. Better Medicines
Management
Ability to view current
medications (known to
GP)
Clinician benefits
• Reduces need to prescribe from
scratch
Patient benefits
• Patients less likely to receive
inappropriate or sub-optimal
prescribing
Service benefits
• Reduced waste
28
• Reduced prescribing costs
4. To improve the
patient focus by
A. Providing safer
care through the
reduction in
medication errors
and adverse drug
reactions (ADRs)
By providing clinicians
with rapid access to
information about a
patient's :
• Allergies
• Adverse
reactions
• Medications
• Significant
diagnoses and
problems
Clinician benefits
• Immediate access to accurate list of
medications
• Definitive list of allergies and
adverse reactions
• Less time spent piecing together
clinical history
• Reduced risk of error e.g. dosage
and generic/branding confusion
Patient benefits
• Less likely to be harmed
• Assurance that the right information
for diagnosis, treatment and care
planning is available where and
when it is needed
• Corroboration of clinical/medication
history rather than interrogation
Service benefits
• Reduction in hospital admissions
• Reduction in length of stay
• Reduction in litigation costs
B. Facilitating
patients to
become partners
in their care
Patient can access their
Summary Care Record
via HealthSpace
Patient choice over
whether to have a SCR,
the content of the SCR
and whether the info
should be shared
Clinician benefits
• Higher compliance rates with
treatment
• Better outcomes
Patient benefits
• Patients able to see and determine
what information is held and shared
29
– greater confidence in treatment
• Patients become more "engaged" in
their own health- better outcomes
Service benefits
• General health improvement:
supports shift from sickness service
to a genuine health service
C. Ensuring patients'
experience is
more
integrated, joined-
up care
Different providers of
care have access to the
same information
Clinician benefits
• Less frustration for clinicians
themselves and on behalf of their
patients
• Better overall care planning
• Better outcomes
Patient benefits
• More confident about care given –
clinicians know what has happened
to patient in different healthcare
settings
• Patients don't have to repeat basic
information about clinical history –
corroboration rather than
interrogation
Service benefits
• Speed up care processes – cost and
time savings from increased
efficiencies
D. Ensuring
confidentiality is
better protected
Patients able to choose
whether to have a SCR
or not and whether it can
be shared
Role-based access
Clinician benefits
• Fewer faxes, telephone calls etc
seeking patient information in
unsecured manner - such requests
become "extra-ordinary"
30
controls
Legitimate relationships
– must be declared by
healthcare professional
before accessing SCR
Patient benefits
• In control for first time over what
information is stored and shared
between organisations
Box 1.1: The anticipated benefits of electronic hea lth record systems (3)
Such positive consequences remain to be clearly demonstrated in practice; a review of the
literature reported that robust, empirical evidence was thus far lacking for many of these
anticipated benefits.(4) It is also recognised in the literature that implementing EHR systems
can potentially introduce harmful consequences. Important potential risks relate to the
accuracy and completeness of the information entered into the electronic record, and to the
security of digital data. Further, the disruptive nature of introducing new technologies into
healthcare organisation and care delivery means that unforeseen consequences, harmful or
positive, are also possible following the implementation and adoption of healthcare
information technology (IT) systems.
For the UK government, introducing nationwide EHRs was a core component of larger,
ambitious, multi-faceted initiative for IT-enabled modernisation of the NHS in England. The
creation of a national IT infrastructure and the central procurement and implementation of
new, standardised computer systems was planned with the aim of raising service quality,
improving patient safety and satisfaction, and enhancing the future sustainability of
England’s universally available, publicly funded NHS. The strategy to deliver the proposed,
ambitious transformation of the NHS in England was named the NPfIT.
1.2 The National Programme for Information Technolo gy
The NPfIT became the focus of domestic and international attention as the world’s most
ambitious and expensive government programme for IT-enabled health system reform. A
series of government publications had prepared the way for its launch in 2002. The
Department of Health (DH) had made a commitment to creating life-long electronic records
for NHS patients four years earlier.(5) Subsequent government publications supported the
strategic goals of improving NHS information systems and of developing more “patient-
centred” service organisation and care delivery.(6-8) In 2002, the Wanless Report
recommended doubling the amount of protected expenditure for NHS IT. Later that same
31
year, Delivering 21st Century IT Support for the NHS – A National Strategic Programme was
published – and the New Labour Government, led by the Rt. Hon. Tony Blair, launched
NPfIT for England (other devolved nations, that together with England make up UK, have
their own national NHS organisations).(9)
Many hundreds of different IT systems were used by NHS staff at the time of the
Programme’s launch. These were usually small-scale systems that had been locally
developed or procured, often for use in a single setting. Different NHS organisations varied
widely in their commitment to adopting new technologies and in the levels IT expertise that
were locally available. There were no secure means of exchanging confidential healthcare
information to support the continuous care of patients who received treatment at different
NHS settings. At the outset, the scope of the centrally managed NPfIT was to create a
national electronic infrastructure – a broadband network to serve all NHS organisations in
England (N3) – to deliver electronic prescription (Electronic Prescription Service) and
electronic appointment booking services (Choose and Book), and to build a life-long, EHR
service for patients in England through the use of a limited range of standard software
systems.
After 2002, the scope and costs increased significantly. In addition to delivering the four,
originally scoped projects, over time the remit of the Programme expanded to include
delivery of a further six, main projects (see Box 1.2), plus a range of activities designed to
support NHS staff in making organisational and clinical changes in parallel with
implementing new IT systems. A 2009 report by the parliamentary Public Accounts
Committee (PAC) estimated that the costs of delivering the whole Programme, as it was
then envisaged, had risen by ~50% to £12.7 billion.(10)
Aspects of delivering the Programme are now generally acknowledged to be successful,
such as building the high-speed broadband network (N3), and the implementation and
adoption of Picture Archiving and Communications Systems (PACS) throughout England’s
hospitals. Others, such as the core NHS CRS, have aroused more controversy and attracted
adverse criticisms. Some of these latter issues are explored in later chapters of this report,
where findings from our evaluation are presented.
1.2.1. Overview of the Programme’s governance and leadership history
At the outset, the Programme was managed directly by the DH. In 2004, following a review
of its “arms length bodies”, the DH announced it would establish a new government agency,
32
NHS Connecting for Health (NHS CFH). The new agency would combine carrying
responsibility for delivering the Programme with taking over some of the functions previously
carried out by the former NHS Information Authority. NHS CFH was created in 2005. Under
the leadership of Mr. Richard Granger, the agency employed staff with healthcare, IT and
management experience, who were drawn from the NHS, academia, the civil service and
from the private sector. NHS CFH underwent a series of organisational and leadership
changes in the course of its existence. A 2007 restructuring saw the introduction of the
National Programme for IT Local Ownership Programme (NLOP). The main changes it
brought were devolving responsibility for local delivery of the Programme from NHS CFH to
groupings of England’s 10 Strategic Health Authorities (SHAs), which were organised to
reflect each of the three, remaining Local Service Providers (LSPs) geographical areas i.e.
the North, Midlands and Eastern (NME), London and the South. NHS CFH then focused on
commercial and legal aspects of the Programme. In a wider reorganisation in 2010, NHS
CFH was brought under the direct management of the DH’s Informatics Directorate.
Under the NHS CFH, a five-year programme of research was set up in 2006. The NHS CFH
Evaluation Programme (NHS CFHEP) is led by the University of Birmingham, which
commissions independent, academic research to evaluate various aspects of the
Programme. These evaluations are intended to inform future NHS IT deployments and more
generally to generate: “…insights into the lessons learned through such large scale
projects”.(11) The evaluation reported here, NHS CFHEP 005, is one of the portfolio of
independent studies commissioned under the NHS CFHEP scheme.
1.2.2 The current state of play in the Programme
Our research was undertaken against the backdrop of an evolving Programme, shifting NHS
strategies and directives (for instance, for maximum time-to-treat targets) and changing
government policies for the NHS in England, which have continued into 2011. The current
UK Coalition Government took office in May 2010. A Government White Paper lays out new
plans for further, substantial restructuring of the NHS in England.(12) The plans include
fundamental changes to the way in which the services of NHS organisations are to be
commissioned, with purchasing powers being taken away from Primary Care Trusts (PCTs),
where they currently reside, and passed to consortia of General Practitioners (GPs). It is
also envisaged that all of England’s acute and mental health hospital Trusts will become
Foundation Trusts. Foundation Trusts have greater financial autonomy and independence
from DH control. Since 2004, when the government introduced Foundation Trust status,
33
some 53% of acute hospital Trusts and 70% of mental health Trusts have made successful
applications under the existing regulations.
More recently, significant changes are following the 2010 Coalition Government review of
the Programme. The DH review concluded that: “… a centralised, national approach is no
longer required”.(13) This statement marked the abandonment of the original, top-down
approach to achieving nationwide healthcare information exchange through deploying new,
standardised IT systems, and the official move to adopting a “connect all’’ approach.
Embracing greater local choice for NHS organisations and the opening up of NHS IT
markets to multiple systems suppliers are likely to be accompanied by a substantially
reduced Programme scope. The national infrastructure delivered through the Programme is
to be retained, while applications common to all NHS organisations, such the electronic
appointment booking service, Choose and Book, are to become services under the control of
the NHS. Simultaneously, the centrally negotiated and managed contracts to deploy NHS
CRS systems in all of England’s NHS hospital Trusts are being pared back. Under the
reduced contracts, the Programme aims to deliver a smaller number of more limited hospital
EHR implementations between now and when the contracts end in 2015.
Finally, at the time of writing, a public consultation on future NHS IT policy – for an
“information revolution” – has just closed, with an announcement on the consultation
outcome expected later this year.(14) The “vision” for an information revolution, in keeping
with the policy document, Equity and Excellence: Liberating the NHS, simply alludes to
people having: “… an accurate record of their care, available to them electronically”.(12) This
may be contrasted with the originally planned NHS CRS, which it was hoped the Programme
would deliver.
1.3 The NHS Care Records Service
1.3.1 The originally envisioned NHS CRS
The original plan for the NHS CRS was to deploy a few, centrally selected and procured
NHS CRS applications for hospitals (and to an extent for the community). This was
predicated on achieving national connectivity through rigorous systems standardisation at
the regional level. The applications would enable the creation of detailed, longitudinal EHRs
that would be set up, stored and updated locally during each episode of routine care. Every
patient would also have an electronic Summary Care Record (SCR) created for him or her to
hold brief, clinical information that could be accessed from anywhere in the country, at any
34
time of day or night, to support appropriate care giving in emergencies. The SCR would be
centrally stored on the NHS Spine, a national database and messaging application, and
together with the local, detailed electronic record, would create each individual’s NHS CRS.
1.3.2 The Programme’s NHS CRS delivery strategy
The DH first divided England into five, geographical, implementation “clusters”. Tenders
were then invited for a LSP to implement new or replacement IT systems to build into the
NHS CRS in each of these. In 2003/4, 10-year LSP contacts were awarded to: Computer
Sciences Corporation (CSC) to deliver the NHS CRS in the then North West and West
Midlands cluster; British Telecom (BT) Capital Care Alliance for the London cluster; Fujitsu
for the Southern England cluster; and Accenture for both the North East and the Eastern
England clusters.
Accenture withdrew from its contact after three years (in 2006). Its former areas were taken
over by CSC, leaving three LSPs in the Programme. These three LSPs were subsequently
reduced to two; legal negotiations between the DH and Fujitsu to revise the original contract
for the South of England stalled in 2007/8, and the LSP contract with Fujitsu was terminated
in May 2008. This placed the South of England area in an anomalous position in the
Programme. It now had no LSP to deploy a single, regional solution for EHRs in secondary
care.
By the end of the year in which the evaluation reported here began – 2008 – the delivery
strategy was for hospital Trusts in the South to choose to take NHS CRS solutions from
either of the two remaining LSPs (BT in London, and CSC in the rest of England) or to
deploy new IT systems using other suppliers approved in an Additional Supply Capability
and Capacity (ASCC) list (see Figure 1.1). The National Audit Office noted that the
Programme’s deployment plans were four years behind schedule.(15)
35
Figure 1.1: The delivery structure for implementing the NHS CRS (16)
1.3.3 The NHS CRS suppliers and applications
Initially, the LSPs’ chosen solutions were to be introduced to all hospital and selected
community Trusts in a Programme cluster, with a scheduled timeline of deployment “slots”.
The plan was designed to allow LSPs to deliver incremental releases in the functionalities of
the NHS CRS applications to hospitals. The bundled releases planned for BT’s solution for
acute hospitals, Cerner Millennium (hereafter referred to as Millennium), are shown in Figure
1.2. Those for Lorenzo Regional Care (hereafter referred to as Lorenzo), the CSC solution,
are given in Figure 1.3.
36
Figure 1.2: The intended phased implementation of M illennium Software in London
(17) (permission to reproduce in the process of bei ng applied for)
Clinicals I Clinicals II Clinicals III Clinicals IV
TTO Prescribing
Inpatient Prescribing
Theatres I
Maternity
Theatres II
Release 1 Release 2 Release 3 Release 4
Care Management I
Requests & Results
Clinical Documentation
Care Plans I Care Plans II
Daycare
Emergency Care
Mental Health Care Management
Care Management II Care Management III
GP
Disconnected Mobile
Surveillance and Screening
Figure 1.3: The intended phased implementation of L orenzo software (18) (permission
to reproduce in the process of being applied for)
Each LSP was given responsibility for choosing and sub-contracting a software supplier.
CSC chose iSOFT and, with them, planned to develop, build and deploy a new NHS CRS
37
application, Lorenzo. Cerner is the supplier sub-contracted by the LSP, BT, to provide
Millennium, which was already an established healthcare IT system in the USA. However,
Millennium was only adopted as the strategic solution for acute hospitals in London after an
initial arrangement for a different, single, London-wide solution had fallen behind schedule: a
contract re-set in 2005 first saw “interim solutions” for London – Millennium, and the CSE-
Servelec (subsequently CSE Healthcare) web-based application, RiO, for community and
mental health Trusts. Initially in 2004, BT had chosen an IDX solution for both acute and
mental health Trusts in London, mirroring Fujitsu’s decision to sub-contract IDX for its NHS
CRS solution in the South. Fujitsu subsequently replaced IDX with Cerner.
In London, both RiO and Millennium were adopted as the strategic solutions after a further
contract re-set in 2006, which moved BT away from aiming for a single supplier (IDX) for
London and endorsed the LSP’s use of multiple suppliers in a “best of breed” approach. The
history leading up to the current LSPs’ NHS CRS-related solutions for secondary care is
given in Box 1.2 and the present position illustrated in Figure 1.1.
1998
• NHS Executive commits to detailed EHRs
2002
• National Programme for IT for England (the Programme) starts
• Richard Granger appointed NHS Information Technology Director
2003/4
• BT awarded contract for the central database and messaging service, the NHS Spine
• LSP 10-year contracts awarded:
CSC - North West and West Midland cluster; BT Capital Care Alliance – London cluster;
Fujitsu - Southern cluster; Accenture - North East and Eastern England clusters
• CSC plans to work with subcontracted supplier, iSOFT, to develop a new application,
Lorenzo; BT and Fujitsu plan to work with subcontracted supplier, IDX Corporation, to
implement the application, Carecast
• BT awarded N3 (NHS broadband network) contract
2005
• NHS CFH set up to deliver the Programme
• BT contract re-set 1 for “interim solutions” in London (until Carecast strategic solution
becomes available)
• Fujitsu replaces IDX as its supplier and subcontracts instead to Cerner to supply Millennium in
38
the Southern cluster
2006
• Accenture withdraws as LSP; CSC awarded 9-year contract for Accenture’s former clusters
• BT drops Carecast as a London-wide solution and appoints Cerner as its main subcontractor
for acute hospitals in London
• “New Route Map” for London proposals include:
o “best of breed” approach, i.e., three main subcontracted suppliers instead of one – to
supply Millennium for acute Trusts; RiO for community and mental health; and INPS
Vision for general practice
o London-wide integration engine, connected to the NHS Spine, proposed to enable
London Shared Patient Records
2007
• NLOP introduced (devolved responsibility for local delivery of the Programme from NHS CFH
to groupings of Strategic Health Authorities; replaces original, 5 clusters with 3 Programme
areas - Southern (LSP, Fujitsu), London (LSP, BT) and NME (LSP, CSC)
• BT contract re-set 2 for “best of breed” London solutions
2008
• Fujitsu LSP contract in Southern area terminated, leaving no LSP in Southern area
• BT contract re-set 3 negotiations for New Delivery Model in London (to permit London Trusts
– limited – opportunities for local configuration and build of Millennium and mixing
components from originally planned Release Bundles (see Figure 1.2))
• Richard Granger, head of NHS CFH, leaves in January; Gordon Hextall, acting head, leaves
in April; Christine Connelly and Martin Bellamy appointed to jointly lead NHS CFH in
September
2009
• BT awarded additional contract to take over 8, formerly Fujitsu/Millennium Trusts (7 following
merger of 2 Trusts), plus 25 Trusts for RiO and 4 additional, acute Trusts in Southern area
• Other Southern Trusts given choice of LSP solution from BT or CSC or from various suppliers
in ASCC
• Martin Bellamy, Director of Programmes and Systems Delivery, NHS CFH, resigns
• NHS CFH, headed by Christine Connelly, Chief Information Officer for Health at the DH, is
integrated with DH Informatics Directorate
• Parliamentary announcement of contract renegotiations with BT and CSC/seeking NPfIT cost
savings
2010/11
• May: UK General Election: New Labour Government replaced by a Conservative-Liberal
39
Democrat Coalition Government
• New Memorandum of Agreement signed between BT and NHS CFH for reduced number of
NHS CRS deployments in London; also negotiations to pare back LSP contract with CSC
• London-wide integration engine plan dropped
• Government review of the Programme confirms that the original, standardised “replace all”
approach is to be replaced with a (standards and interoperability-based) “connect all”
approach; NHS IT markets opened up to multiple suppliers
• Outcome of a Department of Health Public Consultation on NHS IT expected in 2011
Box 1.2: History of the National Programme for IT a nd its Local Service Providers and
suppliers for the NHS Care Records Service
1.4 Evaluating electronic health record systems
In planning this evaluation, we reviewed the expanding body of literature on the evaluation of
EHR implementations in individual hospital settings and of small-scale or focused IT
implementations.(19-23) Given that there was very limited experience with implementing
large-scale, national IT systems in healthcare until recently, there is limited, directly relevant
evidence available that could be drawn on to guide our evaluation and, as has become
apparent through subsequent publications, the best evaluation methods are contested.(24-
26)
More generally, it is apparent that the wider field of health information systems evaluation
has over the last two decades broadened from a narrow focus on understanding the
“economic benefits” of EHRs to a wider set of interests and concerns, including assessing
their “impact” on the quality, safety and efficiency of patient care – the term “impact” implying
a strong, temporally focused and unidirectional causality at the heart of the evaluation
practice.(27) This concern with assessing impact has led to calls from some quarters for the
greater use of randomised controlled trial (RCT) designs.(28) These calls have however
been countered by arguments that, despite their apparent robustness, RCTs are impractical
due to the impossibility often of randomising parts of a hospital or hospital system, and by
more fundamental concerns regarding attempts to “control” for potentially important effect
mediators and the difficulties of measuring the effects of a generic health service innovation
on a diverse array of outcomes.(24) One response to such concerns has been the argument
for more “quasi-experimental” or “observational” studies evaluating EHRs in practice.(29)
More recently, it has become common to find the implementation of EHR systems described
as complex change management interventions that require a well-articulated vision and
40
strategy, strong leadership, appropriate resources, good project management, an enabling
organisational culture, effective communication and attention to human resource
issues.(23;30) The importance of four key components – technical, human, project
management, and “organisational and cultural” change – has been emphasised as
necessary for ensuring a successful process of adopting EHRs.(2;31;32) These components
and their interconnections highlight the need for multi-faceted methods to reflect far more
complex challenges than those that relate solely to the technology. Thus evaluation is
moving towards an approach that can encompass the complex environment in which the
technology is introduced and used.(33-35) This has catalysed a shift towards using multi-
method approaches that allow exploration and contextualisation as part of evaluation.(29;36-
38) This view assumes that EHRs are not simple IT projects amenable to management
control, but are interrelated with organisational and social dimensions.(39) It is also now
increasingly accepted that evaluation activities need to be formative and multi-faceted so as
to capture the experiences of implementation as perceived by diverse stakeholders in
complex healthcare settings.(25;36;40-42) Such approaches seek to integrate quantitative
and qualitative components (“methodological pluralism”) in order to assess not only the
outcomes and consequences of EHRs but also to explain how they come to work (or
conversely how and why they fail to work).(43-46) Imaginative approaches to evaluation in
this spirit are able to bypass assessing progress against predefined criteria and milestones,
and give researchers the opportunity to ‘tell the story’.(47)
1.5 The structure of this report
After this introductory chapter, Chapter 2 gives the aims and objectives of our evaluation of
the NHS CRS in secondary care, and this is followed by an overview of the research
strategy and methods that were employed in our evaluation (Chapter 3). The more detailed
objectives, methods and main findings of the various facets of our evaluation are then
presented (Chapters 4-7), beginning with themes derived from qualitative data from multiple
case studies (Chapter 4). Chapter 5 details related investigations to try to understand the
local costs in NHS CRS-related implementations. The report then presents quantitative work
undertaken in hospital outpatient clinics, which aimed to assess the consequences of IT
implementations for patient safety through a cross-sectional and controlled, before-after
study of the completeness of information available in clinics (Chapter 6). These findings are
drawn together and expanded in Chapter 7, where the content attempts to provide a broader
context for the evaluation and begin to tease out the implications of this work. Finally,
Chapter 8 summarises the findings from the overall evaluation and presents the conclusions
and policy recommendations that may be drawn from this research. Relevant supporting
41
material is presented in the Appendices. Recognising that some readers may only read
certain chapters, all abbreviations are spelt out in full with the first usage in each chapter.
Key terms are also explained in the glossary.
We are currently working on a number of more academic presentations and publications that
will draw on and develop further the themes covered in this report.
42
Chapter 2: Aims and over-arching objectives
2.1 Aims
We sought to undertake a formative and summative evaluation of the implementation and
adoption of the National Health Service Care Records Service (NHS CRS) with a view to
informing local and national strategic implementation decisions on the implementation and
adoption of the NHS CRS. In doing so, our aims were to:
• Investigate the early releases of NHS CRS systems (i.e. Lorenzo, Millennium and
RiO) across a variety of dimensions that are reflected in our six work-packages
(WPs).
• Liaise with NHS Connecting for Health (NHS CFH) throughout the evaluation in order
to inform both local implementation and plans for the national roll-out of the NHS
CRS.
2.2 Objectives
Our main over-arching objectives were to:
• Explore different implementation processes of the NHS CRS within their wider
organisational, political and economic contexts.
• Explore the attitudes, experiences and expectations of the various stakeholder
groups over time.
• Investigate the evolving organisational consequences expected, for example, in
relation to organisational workflows, professional role and data quality
transformations.
• Assess and understand the costs of NHS CRS implementation.
• Investigate whether the introduction of the NHS CRS resulted in improvement in the
quality of care.
• Summarise and integrate the findings with wider contextual considerations and make
suggestions for future deployments and research.
Research activities were organised into six complementary WPs that were approached as
methodologically closely related and, where appropriate, as sharing theoretical approaches,
field work activities in data collection, and analytical themes. Each WP had its own more
specific objectives (see Chapters 4-7).
43
Whilst our core aims and objectives remained, we, for several reasons beyond our control,
needed to rethink some of the premises underpinning the commissioning brief and our
response to this, and, with the support of the funders and guidance of our Independent
Project Steering Committee, realign the focus of this work and revise some of our more
detailed objectives. The main reason for this realignment was the very limited deployments
of the NHS CRS and, even in instances where systems had been deployed, the limited
clinical functionality of these systems. This therefore led us to focus more on the formative
local component of our work. Furthermore, the fact that ePrescribing functionality had not
been deployed rendered it impractical to conduct our planned quasi-experimental
evaluations in relation to assessing the impact of the NHS CRS on this important safety
indicator. There was also a strategic shift from a top-down deployment of a limited number of
standardised software systems to an increasing emphasis on local choice in relation to the
system functionalities that were to be implemented, hence our move to a case study-based
approach (see Chapter 3). This shift towards a more locally tailored approach was
accelerated following the May 2010 election and the associated change in government. We
also (in keeping with national bodies such as the Audit Office and Public Accounts
Committee) faced challenges in accessing relevant financial information on the costs of
deployment, these being explained by reference to confidentiality clauses and concerns
about the releases of commercially sensitive data, which also necessitated a change in
emphasis in relation to some aspects of our economic work (48;49). Although some
revisions to our research plans were necessary we remained, as far as possible and
appropriate to do so, true to our original detailed research objectives. We have, in the
interests of transparency, detailed our original research objectives in Appendix 1 and detail
our revised objectives in relevant chapters focusing on individual WPs in detail (see
Chapters 4-7).
44
Chapter 3: Overview of methodology
3.1 Introduction
We conducted a prospective multi-faceted mixed methods evaluation of the implementation
and adoption of the NHS Care Records Service (NHS CRS) in order to generate insights
that could support the implementation of the NHS CRS in ‘early adopter’ sites (formative
assessment) and the future roll-out of the NHS CRS to other settings (summative
assessment). The research was classed as a service evaluation by the NHS Research
Ethics Committee (ref. 08/H0703/112; see Appendices 2 and 3 for details on approval
documentation). This Chapter provides an overview of the overall methodology employed in
this evaluation; more details of our methods in relation to individual work-packages (WPs)
are provided in Chapters 4-7.
Our plan was to track developments over time in a number of NHS Trusts across England,
undertaking a series of before-during-after assessments. Although commissioned to begin
our research well after the start of the Programme, because of the delays in implementation,
we still began our evaluation before any substantial implementations of the NHS CRS had
taken place. These delays however continued well into our evaluation period, which made it
impossible for us to pursue the original plan of assessing these software systems once they
had had an opportunity to embed within NHS sites. Our evaluation was also hampered by
the fact that the implementations that did begin tended to involve limited deployment of
clinical functionality, which impacted on our ability to study the proposed safety and quality
indicators. Also of relevance was that there was a discernible move away from “standard”
solutions to more customised deployments in which NHS sites not only had a degree of
choice in the particular safety modules to be deployed, but also in the approach to
implementation. These changes forced us to reconsider aspects of our plans, moving to a
predominantly qualitative case study-based approach. Quantitative aspects of our original
research approach were however maintained in as far as it was still appropriate to do so.
3.2 Theoretical background and approach
Our original proposed theoretical approach was informed by a “realistic evaluation”
perspective,(46) which sought to understand what works and for whom and in which
contexts. However, because of the changing landscape and our evolving appreciation of the
nature of the NHS CRS, and its various manifestations, we shifted towards a more focused
45
sociotechnical approach drawing primarily on Cornford et al.’s (1994) sociotechnical
framework to help shape and frame data collection and analysis (this will be explained in
more detail in Chapter 4).(50)
Our initial plan was also to study quantitatively the effectiveness of the NHS CRS in
improving safety outcomes relating to prescribing indicators, the quality of information
provided on discharge and missing information in outpatients departments using a quasi-
experimental design. The proposed stepped-wedge design would have allowed us, we
envisaged, to undertake a series of controlled before-after evaluations as deployments of the
NHS CRS proceeded (see Chapter 6).(51) However, it became clear that, in the light of our
emerging understanding of the implementation landscape, this approach was no longer
appropriate for a variety of reasons, these including:(52)
• The original assumption underpinning the research call and our proposal was that
the different software systems that constituted the NHS CRS (see Chapters 1
and 4) would all provide broadly comparable functionality such that it was
possible to make an overriding assessment of the effects of the NHS CRS;
shortly after beginning our fieldwork, it however became clear to us that this was
more aspirational rather than reflecting the reality on the ground.
• There were furthermore major regional changes, such as the withdrawal of a
Local Service Provider (LSP) in the South and contract renegotiations in the
North, Midlands and Eastern (NME) and London regions, which needed to be
accounted for in our evaluation.
• Considerable delays in the implementations in all regions resulting, for example,
from delays in release of software updates.
• The limited clinical functionality being deployed.
• Trusts developing their own local deployment strategies by prioritising and
working on the functionalities they were most interested in, resulting in difficulties
in making any meaningful comparisons between sites with their varying software
and implementation processes.
In view of the above initial insights, it became clear that we needed to focus less on the NHS
CRS as a discrete entity and more on how the NHS CRS comes into being (is formed)
through people’s understanding and actions, i.e. how it is “performed”.(53) This led to shifts
in our approach; the focus was now directed, not so much on evaluating and thus making
implicit judgments as to what was ultimately achieved, but more to understanding and
narrating the stories of the NHS CRS in-the-making through the lens of a sociotechnically
framed and performative, rather than a deterministic and linear ontology.(44;54) Case
46
studies allowed us to acquire insights into the implementation and adoption strategies of
‘early adopter’ sites by enabling us to understand how they understand the NHS CRS, the
processes of change it triggers, the reasons for adopting particular strategies, as against
others, and the expectations relating to these implementations.
Our case studies were in-depth and longitudinal; their purpose was to understand how each
site perceived and performed the implementation and adoption of the NHS CRS from
inside,(55-57) and how this varied over time. We spent considerable time in the settings we
investigated, interviewed the range of people who were affected by these implementations,
observed their practices (whenever this was possible) and read through a variety of
documents that provided contextual insights.(58) In doing so, we gained rich insights into the
complexities associated with individual sites.
We defined a case study as a NHS organisation (Site) which planned to and/or commenced
implementation of one of the three core NHS CRS software systems (i.e. Millennium,
Lorenzo or RiO) as part of the National Programme for Information Technology (NPfIT), in
which we undertook qualitative or quantitative field work. Our field work was undertaken
predominantly in those sites that ultimately satisfied this definition, but some field work was
also undertaken in a broader range of sites from which case study sites were ultimately
selected. Appendix 4 gives a summary of each individual case study in this evaluation.
3.3 Sampling
The general rationale for sampling case study sites and interviewees was adopted from
Patton:
“Qualitative sampling designs specify minimum samples based on expected
reasonable coverage of the phenomenon given the purpose of the study and
stakeholder interests” (59)
We considered the importance of broadly considering Patton’s phrase “stakeholder interests”
to select participants using purposive sampling to identify diverse Trusts (teaching versus
non-teaching hospital, Foundation versus non-Foundation, and acute versus mental health
settings) across the Programme’s geographical implementation areas (i.e. London, NME and
Southern England) and to include sites implementing all three, centrally procured hospital
applications (Lorenzo and Millennium for acute hospitals and RiO for mental health).(59) We
sought to have a sample of ‘early adopter’ sites at which NHS CRS-related activity was
47
taking place and from where the breadth and, more importantly, the depth of enquiry could
generate potentially transferable lessons.(60;61)
Within each of the case studies, we aimed to recruit a diverse range of interviewees, actively
seeking different perspectives.(62) We used a purposive sampling strategy to identify
relevant individuals at the Trust level, and if appropriate beyond, using snowball or chain
sampling.(63) Trust interviewees from case studies included hospital and community mental
health managers, implementation team members and IT staff, doctors, nurses, allied health
professionals, administrative staff and, where appropriate, patients and carers. In addition,
we purposively sampled knowledgeable individuals who were not NHS Trust staff and who
offered additional perspectives on implementing the NHS CRS. Interviewees here came
from NHS Connecting for Health (NHS CFH), Strategic Health Authorities (SHAs), LSPs,
and system developers.
3.4 Methods
In keeping with the aims and objectives of our study, multiple methods were used to collect
data in this evaluation. Qualitative data collected at each case study site consisted of Trust
documents, transcripts of semi-structured, face-to-face, telephone and email interviews, on-
site observations and accompanying field notes (see Table 3.1 for our complete dataset) and
surveys and questionnaires for quantitative assessments. We also reviewed specialist IT
publications, national media reports and publications by parliamentary and professional
bodies to track the wider context, or macro-environment, in which implementation took place
(see Chapter 7). Where possible and relevant, data collection at each site took place in two
phases, namely Time 1 (T1) and Time 2 (T2), attempting to consider a six to nine months
gap between the two phases. T1 data collection finished at each of the case study sites
when the research team judged that saturation had been achieved, i.e., no new, rich, diverse
data relevant to the evaluation were being acquired. This was in part influenced by setting
factors, such as the scale of the deployment at the site (e.g., limited to a ward or hospital-
wide) and type of functionalities being introduced (e.g., ordering tests or clinical notes). Data
collection periods varied by site (see Table 3.1); all of the data reported here were collected
between February 2009 and January 2011. Where possible, we revisited sites at T2 in order
to understand how implementation had progressed.
48
Total number of
interviews (by Work
Package)
Hours of on-site
observations; no.
of sets of field
notes
Total number of
documents
collected
Quantitative data collected
(surveys)
Total: 431 interviews
(WPs1-3: 301
WP4: 37
WP5: 58
WP6: 35)
590 hours of
observations;
234 sets of field
notes
809 130 CLICS surveys; 4,684
outpatient surveys
Table 3.1: Overview of our complete dataset
Our research was conceptually divided into six inter-related work-packages (WPs), reflecting
the various qualitative and quantitative aspects of interest. Figure 3.1 below presents a
diagrammatic overview of these WPs and their inter-relationships.
Figure 3.1: Diagrammatic overview of our research
In the following paragraphs, we provide a broad overview of the qualitative and quantitative
Work Package 1 Implementation, deployment and organisational learn ing
Interviews with LSP roll-out teams, members of the implementation planning team and trainers/support staff, quantitative tool to assess the extend of
quality and use of systems (data collection at T1 and T2)
Work Package 2 Attitudes, expectations and experiences of stakehol ders Interviews with patients, healthcare professionals, managers, IT service providers, IT support personnel, administrative staff
(data collection at T1 and T2)
Work Package 3 Organisational consequences: organisational workflo w, professional roles
and data quality Record reviews, interviews with healthcare professionals and administrative staff
involved in the pathways, documentary analysis of relevant documents (data collection at T1 and T2)
Coordinated recruitment of participants for
interviews
Work Package 4 Assessment of costs of NHS CRS implementation
Quantitative framework to identify provider-specific implementation costs, comparing different NHS CRS systems; comparing the same system being implemented in different hospitals;
and comparing implementation of systems in different service delivery environments
Work Package 5 Assessing error, safety and quality of care
Quantitative assessments of missing information in outpatient clinics Before and after comparisons
Work Package 6 Organisational consequences and implications for fu ture IT deployments and evaluations
Summary of findings/conclusions, implications for policy development and implementation, interviews with software suppliers, politicians and members of professional bodies
Feed into
49
methods employed in our work. More detailed methods in relation to individual WPs can be
found in Chapters 4-7.
3.4.1 Our qualitative work: interviews, observation s and documentary data
Semi-structured interviews
Interviews were the main method of data collection for the qualitative parts of this evaluation.
We explored perceptions, meanings, attitudes, past experiences, definition of situations, and
constructions of a reality in relation to the NHS CRS.(59) We used a generic guide adapted
to particular groups of interviewees (see Appendices 5-10). These consisted of a
combination of open-ended core questions and more in-depth probes.(64) Specific questions
emerged as the interviews unfolded, and the wording of those depended very much on the
directions the interviews took.(65) Interviewers tried to be open-minded, to introduce
divergent questions at the times, and also to take into account any new concepts and
frameworks proposed by the interviewees.(66)
In addition to an explanation of evaluation and interviewees’ rights, interviewees were, where
possible, provided with an information sheet containing a summary of the study,
expectations from the interviews, their rights, their potential contribution to the study, ethical
considerations like data confidentiality, and the lead researcher’s profile and contact
information at least several weeks in advance. This was however not always possible as
some interviews were conducted more opportunistically. Most interviews were digitally
audio-recorded (with the interviewees’ verbal consent). For some interviews, participants
requested not to be recorded, in which case the researcher took notes. The recording was
checked after each interview, the interview process critically reviewed, and the interview
schedule amended if necessary. Professional transcribers transcribed the interviews
verbatim, with the interviewers then checking the transcripts for accuracy. Copies of the
transcripts were, wherever possible, made available to interviewees, although only a minority
requested to see these. Occasionally, some direct attributable quotes were also checked
with interviewees.
Observations
To complement the interviews, some researchers observed the changes in actual practices
in hospitals and some affiliated community centres across the recruited Trusts and took
notes relating to these observations. The approaches adopted varied including use of a
simple checklist for observing various NHS CRS applications in use, computers, facilities,
50
practices, and how staff used the NHS CRS in their day-to-day practices. Where possible,
some researchers also sat with staff to observe different NHS CRS applications and the
ways in which these interfaced with, for example, the Spine, the way they used their
SmartCards, the log-in, and the way they put notes on the NHS CRS application. Some
researchers were given a personal informal presentation of the NHS CRS application in use,
usually by a member of the implementation team. Our study team also had in vitro
presentations of the major systems of interest (i.e. Lorenzo, Millennium and RiO), these
being arranged with the support of NHS CFH. In addition, some Trusts invited the lead
researchers to sit in NHS CRS Board meetings and user group meetings as an observer,
which was a useful and informative means to update the latest status of deployment in
details and to identify potential interviewees for our ongoing evaluation.
Documentary data
Documents including public papers, agenda papers, internal documents, minutes of various
meetings, correspondence, bills and legislations, annual reports (official and unofficial),
reports on evaluation of practitioners’ performance, magazines, newspapers, emails, etc,
were a rich source of data in this evaluation (see Appendix 11 for a sample list of documents
collected).(64) Given the early stages of NHS CRS implementation, documents were the
only source of data for some particular aspects allowing access to a set of events and
processes that was otherwise unavailable.(67) Information derived from documents was
utilised either straightforwardly or interpretively, to produce primary research findings or for
verification purposes.(59) Documents were also used as supplementary sources of data to
validate other data.(65) We further used documents to enhance our understanding of the
NHS CRS, its history, the measures to materialise its deployment, understanding the
strategy for implementing the NHS CRS as well as to provide some quantitative data.
We used a range of documents published by government bodies, particularly the
Department of Health (DH), NHS CFH, the National Programme for Information Technology
(NPfIT) and the London Programme for Information Technology (LPfIT), the Public Accounts
Committee (PAC), and a substantial number of documents from participating Trusts. We
also treated contents of some specific websites such as media articles and NHS CFH as
“documents” to help us keep abreast with key developments. We in particular selected
documents that:
• Explained the history of development of the NHS CRS
51
• Reported the progress of implementation and adoption of the NHS CRS and
challenges ahead
• Described the policy, its benefits, prospective outcomes, etc
• Expressed business plans, expenditure, scenarios for deployment, risks and
benefits; lessons learned
• Explained progress of implementation, stakeholders’ attitude and decisions made
to address such concerns, and organisational correspondences
• Prepared to educate various groups of practitioners and public regarding the
NHS CRS applications and their revisions.
Examples of specific documents collected from Trusts included: copies of the Trust’s
organisational structure; NHS CRS deployment timelines; Project Initiation Documents
(PIDs); Business Cases; Risk Registers; minutes from NHS CRS-related board meetings;
lessons learned documents; training strategy documents; and annual reports. Additional
relevant local documents, such as work process maps, were collected where these were
accessible. A comprehensive list of the documents that were obtained and studied is
available on request.
Data analysis
In most qualitative research, analysis begins during data collection; this has the advantage
that any early and developing insights can shape further data collection.(59) Adopting this
sequential or iterative analysis had the advantage of enabling us to go back and refine
questions, develop hypotheses, and pursue emerging avenues of inquiry in later interviews
and observations.(68;69)
Designated lead researchers undertook both the data collection and led the analysis of
individual case studies. Researchers combined deductive, thematic coding guided by a
matrix of sociotechnical factors and inductive coding that allowed themes to emerge from the
data without prior theoretical categorisation.(50;60;61) This involved immersion in the data,
which was achieved by repeated reading of interview transcripts, discussion amongst team
members, development of provisional analytic categories/themes through comparisons with
our theoretical lens and other secondary studies, and iterative refinement of these categories
using the constant comparative method (comparing our analysis to date with new data as
these emerged).(70) Comparison of findings across and between case studies was achieved
through qualitative workshops which allowed individuals to present and share their case
52
study findings and then reflect collectively on the interpretation of these in the light of other
ongoing case studies.
Documents were analysed in a similar way by following an inductive thematic analysis.
During analysis emphasis was placed not only on the content of the documents, but also on
the context they were describing and within which they were produced.(71) Document
analysis intermingled with the analysis of transcripts and observation notes in order to
produce an integrated account of the cases under study.
3.4.2 Our quantitative work: undertaking a cost ana lysis and quality, safety and error
assessments
As already noted, we needed to reconsider aspects of our quantitative work. The changes
made are outlined below, with a more detailed discussion in Chapters 5 and 6.
For the economic work (WP4), we set out to assess implementation costs and develop a
framework for costing that could be rolled-out to Trusts as the NHS CRS was implemented.
We faced a number of challenges in achieving this goal, these including: the widely
acknowledged delays in implementing different NHS CRS systems; difficulties in making
meaningful comparison across sites because of varying functionalities in different releases;
and, most importantly, a reluctance to provide documents containing cost information at a
Trust level – perhaps even more so following the election of an austerity focused Coalition
Government.(72) These challenges substantially limited access to relevant quantitative data
– particularly financial data – that we could obtain. These difficulties were regularly
communicated to NHS CFH and the NHS Connecting for Health Evaluation Programme
(NHS CFHEP), but they too appeared powerless to provide such data.
In light of these challenges, we aimed to construct a generalisable model of implementation
costs at the Trust level based upon their individual experiences. We used a combination of
available cost data, additional available documentary evidence and a number of semi-
structured interviews with, amongst others, finance managers and IT implementation leads,
the purposes of which were to:
• Identify the costs involved in implementing electronic health record (EHR) systems
into NHS secondary care sites
• Derive cost categories and explore the factors that impact on the amount of resource
spent by Trusts in each of these cost categories.
53
Our other quantitative WP aimed to assess the error, safety and quality of care (WP5), with a
focus on those outcomes that were most likely to be influenced by the early releases of the
NHS CRS. Significant health outcomes were unlikely to be detectable within the study
timeframe, and thus indicative process measures were chosen. Four measures were
planned: medication errors; medicines reconciliation on hospital admission; completeness of
information provided at hospital discharge; and availability of key information in medical
records in hospital outpatient clinics. However, as our work progressed, it became apparent
that the repeatedly “revised” (delayed) timescales for NHS CRS implementation would no
longer marry with our evaluation timeline. The clinical functionality, which would influence the
first three process measures, was unlikely to be in place during the evaluation period.
Consequently, although data collection tools for all four measures were developed and
piloted, only the availability of medical records was actually pursued.
3.5 General methodological considerations
Prior, informed consent to join the evaluation was obtained from participating NHS Trusts,
and researchers complied with local requirements for approvals on a case-by-case basis.
Informed consent was also obtained from participating individuals. We have, as far as
possible, sought to protect the anonymity of participating sites and individual participants by
removing identifying information from the data.
Despite traditional attention to the content of the policy implementation rather than the
process, this evaluation concentrated much on the processes contingent on developing and
implementing change and the context within which the policy was developed.(73) This was
necessary to avoid diverting attention from understanding why desired policy outcomes
failed to emerge. We therefore focused on process rather than on the outcomes or impact of
the NHS CRS, acknowledging Reich’s (1994) argument that policy reform is a profoundly
political process, affecting the origins, formulation and implementation of policy.(74) In
addition to difficulties in assessing outcomes only months after start of deployment of the
NHS CRS, evaluating process brought advantages over outcomes. First, comparisons were
not essential in studying the implementation process. Second, direct study of processes
helped identify the obstacles and deficiencies of implementation which needed to be
remedied,(75) which was in line with formative element of our evaluation. Finally, there were
some examples of failure in the process which were likely to lead to poor outcomes.
54
The evaluation also aimed to identify and explain why the NHS CRS on paper was widely
different from what was executed. It was essential therefore to get at the narrative behind the
NHS CRS process, to explore the phenomenon from the perspective of those involved, and
to analyse their views, opinions, and actions. It needed immersion in the policy debates that
took place to identify ideas that were held and influences that held sway.
One of the issues in evaluations such as this is researchers’ views and position, their
institutional base, perceived legitimacy, and prior involvement in policy communities.(76)
This is critical to researcher’s ability to access the policy setting and conduct a meaningful
analysis. This is arguably more important if the analysis requires engaging with policy
elites,(77) and when investigating sensitive issues of “high politics”,(76) very much the case
in our evaluation.
We used a range of approaches to validate data quality and credibility, including checking for
face validity, looking for disconfirming evidence, data triangulation by data source and
seeking informant feedback.(59) The collaborative composition of our research team
enabled researchers to approach the data analysis more critically, corroborate relevant
themes to pursue, read and re-read the data to identify supplementary themes worthy of
exploration. Researchers tried to remain reflexive during the entire process of the research,
and explicit within the analysis.(78) Emerging findings were shared with participating Trusts
for their feedback. Transcripts, codes, emerging findings and their interpretations were
presented and discussed by research colleagues at each stage of the analysis process in
regular team meetings and in multi-disciplinary data analysis workshops and Steering Group
and Independent Project Steering Committee meetings. Discussions and feedback
supported researcher reflexivity and confirmed the interim results’ trustworthiness and
credibility.(79;80)
3.6 Chapter summary
This chapter has sought to provide an overview of the approach we planned to and
eventually ended up pursuing, explaining our rationale for the changes that were made.
Despite these changes, we were however able to maintain key aspects of our evaluation,
namely the multi-faceted longitudinal nature of the enquiry, which sought to understand the
broad range of consequences associated with and resulting from these deployments, with a
focus on the depth of enquiry as a result of which it is we believe possible to generate a
number of important potentially transferable lessons. The details of the methods employed
55
together with the findings from the various WPs are considered in more detail in the following
three chapters.
56
Chapter 4: Understanding local consequences
4.1 Introduction
The first three research work-packages (WPs) and their themes ‘Implementation,
deployment and organisational learning’ (WP1), ‘Attitudes, expectations and experiences of
stakeholders’ (WP2) and ‘Organisational consequences’ (WP3) were closely interconnected
and could not meaningfully be investigated in isolation. Implementation strategies were
strongly tied to stakeholders’ expectations; individual and collective experiences were
shaped by changing organisational work-practices; and organisational learning was both a
means and an outcome of individuals’ experience of National Health Service Care Records
Service (NHS CRS) implementation. This chapter thus presents the findings from these first
three WPs in an integrated manner. We start by briefly reflecting on the contexts of
implementation and adoption at regional (cluster) level and on the different visions of the
NHS CRS as described by different stakeholders. We then report and discuss the different
experiences and strategies of implementations, and the negotiated (clinical, technical,
institutional and professional) locus and focus of change found in the various healthcare
organisations studied. The analysis continues with a focus on the processes of changing,
adopting and adapting to the NHS CRS and the manifestation of these processes in work-
processes, use of technology and information for clinical and administrative needs and data
quality. The chapter concludes with a reflection on processes of organisational learning.
4.2 Aims and objectives
Our aims were to explore past, current and projected NHS CRS implementations and their
organisational implications. More specifically, we sought to:
Implementation, deployment and organisational learning (WP1)
• Explore the rationales and strategies of implementation
• Identify the range of stakeholders involved in the implementation process (intra- and
inter- organisational), explore their relationships and their modes of working
• Study how the wider context (organisational, economic, political) influenced
implementation processes
• Investigate examples of organisational learning and the development of new
competencies
57
• Feedback all the above to support the continuing roll-out of the NHS CRS.
Stakeholder attitudes, expectations, engagement and satisfaction (WP2)
• Explore key stakeholders’ (i.e. including patients/carers, healthcare professionals and
managers) attitudes and expectations of the NHS CRS
• Explore stakeholders’ experiences of the NHS CRS at both early and later stages,
where possible and applicable
• Feedback all the above to support the continuing roll-out of the NHS CRS.
Organisational consequences: organisational workflow, professional role and data quality
transformations (WP3)
• Explore how the NHS CRS influenced professional roles
• Explore transformations in workflows and work practices
• Investigate the role of IT literacy in the implementation of the NHS CRS
• Investigate data quality changes after the introduction of the NHS CRS.
4.3 Methods
4.3.1 Conceptual framework
We took a sociotechnical approach to evaluating the implementation and adoption of the
NHS CRS. In this we were drawn to consider three distinct, but fundamentally intertwined
domains: of technology; of people; and of the organisational settings they work within. The
world that we studied is one where these three elements, each individually of great
complexity, come together and we took it as axiomatic that to understand any one implies
and requires understanding of the other two. There is then no “technical” NHS CRS separate
from the people using it and the organisations that they participate in (see also Box 4.1).
58
Implementation
versus
Adoption
In the context of information technology (IT), the term implementation has always
been ambiguous, for instance referring in the structured waterfall model to either
the ‘building’/‘coding’ stage (coming after requirements elicitation/high level
design, and before integration/testing) or to the stage of ‘preparing the system for
use’ (installation, configuration, data migration, user training, etc.).(81) In the
context of the NHS CRS, we use the term to refer to the latter – i.e. from the
decision to ‘purchase the software package’ to the strategies and activities for
‘preparing the system for use’. However, in the case of Lorenzo, the design of the
system took place during or after its ‘implementation’ (and this term therefore
includes strategies and activities belonging to the stages of requirements
elicitation, design, coding, integration, testing).
While implementation brings the software system in the workplace, adoption
refers to the process by which people within the organisation make it (or not) part
of their work practice. The term adoption (and its negative ‘non adoption’) often
implies and/or conveys a view of ‘static outcome’ of implementation (the software
system is either adopted or not) and it is usually seen as synonym of ‘use’ (or
‘non use’) of the software. However, adoption as a process could manifest itself in
‘use’ as originally intended, or in different forms and degrees of ‘use’ (or ‘non
use’), potentially constantly evolving.
Customisation
versus
Configuration
Both configuration and customisation of a software system aim at making an
existing off-the-shelf software package (its interface, or its front-end or back-end
functionalities) suitable for organisations’ context or their technical requirements
(e.g. compatibility with legacy systems and infrastructures). However, with
configuration we refer to the ‘fine-tuning’ of the system by using pre-existing
software options (e.g. re-programming the software with existing code), while with
customisation we refer to the process of changing the software by introducing
design/software code especially created for the organisation.
“Working-out” The expression ‘Working-out’ signifies a dynamic process of adjustment,
adaptation, improvisations and making of meaning that takes place when the new
technology is introduced to the workplace. It is a sociotechnical process involving
not only individuals in relation to the new technology, but the ensemble of people,
existing and emerging work practices and tools, individuals and organisational
beliefs, assumptions, and expectations.
Box 4.1: Key definitions
59
From the initial proposal the research has been based on a sociotechnical model that
combined these three domains with the process, structure and outcome framing of
Donabedian (see Figure 4.1). This framing was intended to do two specific things. First to
ensure that in data collection we considered and collected data relating to each element,
second to support data analysis that emphasised the connections between the elements.
We need to emphasise that this model is not intended as a means to separate out the three
sociotechnical domains, or the structure from process and outcome, and thus to allow some
tokenistic and disconnected findings on “social issues”. We always remember that the real
world of healthcare is not placed into such boxes, but is a layered and complex assemblage
of all three domains simultaneously in all three states.
Figure 4.1: Cornford et al.’s sociotechnical evalua tion framework 1 (50)
The fusion of the three domains was found in particular and in ultimo in people’s work
practices – the time and place where people (individually and in teams or groups)
appropriate technology as they perform tasks – tasks that contribute to and sustain the
organisation. But, while the ultimate sociotechnical NHS CRS emerged in work practices,
1 The arrows that cut across cells intend to illustrate how context, processes and outcomes may be
conceptualised as co-constituting each other. Reprinted from: Cornford T, Doukidis GI, Forster D.
Experience with a structure, process and outcome framework for evaluating and information system.
Omega, International Journal of Management Science 1994; 22(5):491-504 with permission from
Elsevier.
60
when and as it is used, along the way (during the period of “implementation”) we could see
this combining occurring in the implementation strategies and practices used. This was the
main focus of this research. It thus adopted a process-based perspective that considered the
sociotechnical working out of new ways of working with new technologies. The inherent and
situated combinations this implied is in some contrast to approaches that privileges one
aspect and ignore others, for example, privileging the technology and endowing it with
essential characteristics of, for example, efficiency or safety, or prioritising managerial
interests of control or resource allocation, or prioritising the interests of people (or some
dominant sub-group) for stability and cultural continuity.
Sociotechnical approaches are traditionally and historically associated with a particular
philosophy of systems design in which individual user groups’ interests are strongly
represented, for example through participative processes, and in which the final shape of a
technological solution is able to be negotiated at the time of design and in this way to
represent some reconciliation of diverse interests including those of managers, users or
customers. The primary focus in this tradition is on work teams and groups.(82;83) A strong
echo of this perspective is found in much of the literature around the National Programme for
Information Technology (NPfIT) (and health informatics in general) that calls for more
“clinical engagement” to support electronic health record (EHR) and other initiatives.(84)
The sociotechnical perspective has, however, a broader importance and utility than just as a
means to inform activities of technological or organisational design. It also allows policy
makers, managers, engaged professionals or independent evaluators to balance a concern
with technology’s potential and functionality per se, with the ways such functionality might be
introduced to the organisation, be adopted by groups of users and work teams, and the
cumulative and integrated consequences that emerge as new sociotechnical systems of
work are initiated, established and stabilised.(37;85)
In other words, it is not just the system as designed or the system in use that is essentially
sociotechnical, but also the processes that brings systems into use – the processes of
implementation and of adoption. These two processes might be seen conceptually as
distinct and separable – represented as interrelated processes by which design and
construction is linked to use through implementation and adoption (see Figure 4.2).
61
Figure 4.2: Implementation and adoption as two inte r-related processes
We should note here, how we understand the two words implementation and adoption (see
also Box 4.1). Implementation is the moving of new things and ideas into the organisation or
work place – done to a large degree by others/outsiders – who we may call implementers.
Adoption is the countervailing process by which people within the organisation
accommodate (or not) the new systems or ideas and make them part of their work practice.
In the extreme case technical functionality may be present (implemented – a working
computer at the nurses’ station) but not recognised, considered or used – not adopted and
not appropriated into day-to-day work. More significantly the designed system may be there,
but be used in ways or to degrees that the designer/sponsor/implementer did not foresee,
with unexpected or unpredictable positive or negative organisational consequences.(86)
Both sets of actors – the implementer with their new technology to offer and the users with
their work to do (plus invariably some existing already “adopted” technology often referred to
as legacy systems), have a role in influencing how things turn out in the end, but more
significantly how they are worked out in their duration. In this Chapter we placed particular
emphasis on the sociotechnical processes of “working things out” (Box 4.1), seeing it as
central to developing an understanding of the NHS CRS. The work was thus premised on
the understanding that contemporary healthcare information systems are not essentially
shaped in ex ante processes of analysis and design (with or without strong sociotechnical
processes such as clinical engagement), nor by careful package selection or optimal
implementation activities. Their consequences are thus not clearly apparent at the time of
initial implementation.
NHS CRS
as design or plan
NHS CRS
as actions to
deliver, receive
and understand
NHS CRS
as ‘the way we
work now’
Design and
construction:
a (more or less)
sociotechnical
process
Use within the
healthcare
organisation:
a (more and more)
sociotechnical world
Implementation
more or less
sociotechnical delivery
Adoption
An inevitable
sociotechnical ‘working-
out’
62
Rather the sociotechnical “working out” of a technology within the work and organisational
setting continues over time, perhaps many years, and might be better seen as a set of
improvisations, enactments or transformations rather than as taking any ordered linear
path.(87-89) And it may not be just or even principally the technology and its direct
functionality that is ‘worked out’, but other aspects such as the workflow, team structures, the
professional demarcations and even the organisational form itself.
On this basis, the approach to evaluation we used is to create a detailed narrative of the
process of change (we refer to change as it happens as “changing”) that was initiated by and
represented the NHS CRS. Studying change (before-during-after) implicitly assumes a
movement from one situation to another with the major interest being on where we get
to.(90) This assumption can enable comparisons of static views or “snapshots” of the context
under investigation at various time points. It does not however provide a basis to explain
either the process (i.e. the internal and ongoing “how”) or the reasons (i.e. the “why”) for
change. Our processual perspective allowed us to start to answer such questions, and to
focus on the changing that the NHS CRS brought about. This distinct perspective was also
reflected in the evaluation’s shift away from only comparative studies to case-based studies.
4.3.2 Recruitment
We collected data from a total of 17 different locations. 12 of these met our inclusion criteria
for case study sites. These 12 sites therefore form the main bulk of the data collected, whilst
the other 5 locations have informed our analysis. Please refer to Appendix 4 for summaries
of included case study sites. Please refer to Appendix 4 for summaries of case studies and
to Vol. 2 for more detailed analyses and discussions of the cases. For each site, we
recruited participants by following a purposive and snowball approach. Research participants
differed in both number and job position such as Trust Chief Executive Officers (CEOs), IT
Directors and Managers, Chief Operation Officers (COOs), human resource managers,
clinical leads, junior doctors, consultants, nurses, matrons, allied health professionals,
patients, ward clerks, representatives from Strategic Health Authorities (SHAs), registration
authorities, software developers and Local Service Providers (LSPs) and so forth.
Recruitment was largely dependent upon individuals’ availability and willingness to
participate. Each individual was contacted either directly or through a site’s gatekeeper (i.e.
individuals that control access to potential interviewees in the organisation).
63
4.3.3 Data collection
Data collection periods varied by site (Table 4.1), time frames and length. Overall, data were
collected between February 2009 and January 2011. The type of data collected at sites
included Trust documents, transcripts of semi-structured, face-to-face, telephone and email
interviews, on-site observations and accompanying field notes, and in one site responses to
a survey (Table 4.1). Interviews were conducted with the use of specifically designed
interview guides in accordance with the role of each interviewee (implementation team
members, healthcare professionals, patients etc). As already described in Chapter 3, we
also reviewed specialist IT publications, national media reports and publications by
parliamentary and professional bodies to track the wider context, or macro-environment, in
which implementation took place. We tried to maintain a longitudinal element to our study by
collecting data, whenever possible, at multiple times. For instance, in many cases, we
collected data at two time periods (T1 and T2). The table below presents the total number of
interviews, number of hours of observation, number of documents that we collected and
number of responses we received from our survey for the purposes of WPs 1, 2 and 3. It
represents a sub-set of Table 3.1.
Interviews Observation (no. of
hours)
No. of Documents
collected
Survey (CLICS) (no.
of respondents)
(see Appendices 12
and 13)
301 229 720 130
Table 4.1: Data collected for the purposes of WPs 1 -3
4.3.4 Data analysis
Data analysis was an iterative process and followed an inductive process. It was a two-step
approach. Data were initially analysed at a case study-based level. Case study leads
followed a thematic approach to analysis. Data were analysed through repeated reading of
transcripts, field notes and documents and themes were developed bottom-up based on a
combination of deductive and inductive approaches, which were influenced by each
researcher’s academic background and the sociotechnical framework described above. The
process of analysis was repeated after each data collection period (e.g. T1 and T2) when
this was applicable. Themes were refined after being related to each other and compared to
the findings from the wider literature. The findings we present below constitute an outcome
of the second stage of analysis, a meta-synthesis that drew upon the analytical themes from
all case studies.
64
Primary findings from our data analysis processes were fed back to participating Trusts
through formative feedback sessions. These were in many cases interactive sessions during
which researchers would present findings and analytical remarks, with the opportunity for
individuals and Trust representatives to comment on, confirm or disagree with these
preliminary findings. The feedback received was taken into account in the final analysis of
the case studies.
4.4 Main findings
4.4.1 The context for deployment and adoption
The software systems that embody the NHS CRS were, as explained in Chapter 1, deployed
on a geographical basis, with distinct approaches and structures for each cluster2. As
explained earlier (see Chapter 1), when our research was commissioned there were three
clusters: North, Midlands and East (NME); London; and the South. However, by the time that
our study began, Fujitsu, the LSP for the South had exited and there was therefore no
contracted supplier for this whole region.
In the sections below we briefly outline the history and the specific software systems that
each cluster was implementing.
For the various reasons described below, and more generally as part of the original
conception of NPfIT, this cluster model provided a large natural experiment in alternative
ways of approaching the establishment of software systems to underpin EHRs in secondary
care, in both acute and community settings.
In particular, and as exemplified by the metaphorical section headings used below, we see
contrasts between the incremental and iterative practice found in NME, where software
systems for acute and community care were being written as they were being deployed
(iSOFT Lorenzo), and the use in London and the South of an established and large-scale
packaged software system developed outside the NHS context (Millennium).
In the former case, high degrees of customisation were potentially possible with opportunity
for significant input by clinical staff in the early phases. The software provider iSOFT had a
2 We recognise that the term “cluster” is now officially redundant within NHS CFH; however, we have retained it
here as a useful phrase to indicate the three distinct deployment mechanisms and software supply chains.
65
substantial software base in the UK, and was a major provider of patient administration
systems (PAS) with their iPM product. In contrast, Millennium was an older product, with the
potential for customisation, but without an explicit offer of deep customisation in the NPfIT
contract. Its main customer-base was in the USA. There was, at the time of its selection as
part of NPfIT, one independent, Millennium implementation in a London organisation.
In the case of community and mental healthcare settings in both London and the South, the
product chosen was RiO from Customer Satisfaction Everytime-Servelec (CSE-Servelec).
This was also a mature product, but one that had been developed in the NHS context and
for community care. Within the NME cluster, Lorenzo was also used in community care.
Building while using: NME Lorenzo
Lorenzo is a specific type of web-based EHR software implemented in the NME cluster of
England. This cluster was previously planned to be divided into three geographical areas
including the East & East Midlands, the North West & West Midlands, and the North East.
When the contract with Accenture, one of the LSPs responsible for implementing NHS CRS
software in the North East and East & East Midlands, was terminated in January 2007 (see
also Chapter 1), responsibility for implementing NHS CRS software in these regions was
transferred to the LSP of the North West & West Midlands (Computer Sciences Corporation,
CSC).
CSC’s strategic solution was Lorenzo software developed by iSOFT. It was originally
planned to be implemented as a single integrated solution across both primary and
secondary care settings. This scope, however, was subsequently reduced to exclude
primary care settings because contracts were repeatedly renegotiated in order to reduce
costs in an increasing climate of economic uncertainty. Another reason was the reluctance of
primary care settings to implement a product that was still under development and their
preference for Systems One/TPP solution. This has led many to suggest that the strategic
direction should change from an initial focus on integrated care records towards
interoperability of existing systems based on standards.(91)
The NME cluster was the largest of the three NPfIT clusters. It covered approximately 60%
of England and included the following SHAs:
• East Midlands
• East of England
• North East
66
• North West
• West Midlands
• Yorkshire and Humber.
Altogether, these SHAs covered 89 Primary Care Trusts (PCTs), 87 acute Trusts, 28 mental
health Trusts, five ambulance Trusts, and 10 specialist Trusts (including social and
community care).
Lorenzo software was itself unique in many ways. Perhaps one of its most outstanding
features, which also differentiated it from the other NHS CRS solutions, was that it did not
during the course of our evaluation (and indeed still does not) exist as a fully functional
product. The original intention behind its selection was to develop in collaboration with the
NHS a system that is tailored to the needs of its users.
Different releases became available as soon as they were developed in Chennai in India,
where most of iSOFT’s engineers were based. Although releases had to be implemented
consecutively, organisations were to some extent free to choose which parts of releases
they wished to implement according to their needs.
In order to meet users’ needs and to realise benefits, CSC delivered the iPM solution (also
developed by iSOFT) to many Trusts across the NME area. iPM was an electronic PAS
system with basic functionality and Spine integration, installed as a first step towards the
final Lorenzo EHR solution. iPM was designed to deliver some early benefits to Trusts, but
was planned to be substituted by the final solution eventually. iPM was therefore referred to
as an “interim solution”. It is expected that CSC will stop supporting it in 2013.
As of December 2010, Lorenzo Release 1 (R1) was used on a relatively small scale in one
mental health Trust, two community Trusts, and three acute Trusts. Lorenzo Release 1.9
(R1.9) was also implemented in two acute Trusts and one community Trust. Its
implementation was significantly behind schedule and implementations had been
characterised by often publicly debated problems, combined with the limited scale and
functionality deployed.(92) Details of Trusts and Lorenzo Releases implemented to date (at
the time of writing) can be found in Table 4.2 below.
67
Trust Release and go-live date
South Birmingham PCT R1 in September 2008
Morecambe Bay Hospitals NHS Trust R1 in November 2008
R1.9 in June 2010
Bradford Teaching Hospitals NHS Foundation Trust R1 in April 2009
Hereford Hospitals NHS Trust R1 in September 2009
Five Boroughs Partnership NHS Trust R1 in October 2009
NHS Bury R1.9 in November 2009
NHS Stockport R1 in December 2009
Birmingham Women’s Hospital NHS Foundation Trust R1.9 in November 2010
Table 4.2: Trusts and Lorenzo Releases implemented to date
In Lorenzo Release 1 (R1), iPM and Lorenzo ran in parallel. The functionality of R1
implemented was somewhat dependent on the setting and included clinical documentation,
service requests and electronic discharge functionality. Lorenzo R1 was not integrated, but
interfaced with iPM. Lorenzo PAS integration (and replacement of iPM with the Lorenzo
PAS) took place with the introduction of R1.9.
During the implementation of Lorenzo in NME there was a parallel running of both paper and
computer systems. Lorenzo was implemented in a “soft” mode with paper systems being
gradually replaced with electronic systems in selected parts of the Trust initially. Releases of
Lorenzo with increasing capabilities were slowly rolled out to other settings in the
organisation (although this could only to a certain extent be done with R1.9, because as a
PAS replacement it needed to be implemented on a relatively large scale).
Opening the package: London
Greater London had 32 acute hospital Trusts, 10 mental health Trusts, 31 PCTs and more
than 1,600 GP practices to serve an ethnically mixed population of over seven million
people.
In the past, as in other areas of the country, individual NHS organisations in London
developed or bought IT systems locally in ways that created healthcare “information islands”.
Prior to the launch of the Programme in 2002, the (then) five London SHAs decided to pool
resources to deliver patient-centred information systems to support the patient journey
across London healthcare settings. After 2002, this vision of an integrated care records
service for London was commuted into the NHS CRS. At the time of the evaluation London
68
had a single SHA, NHS London. The London arm of the national Programme, the London
Programme for IT (LPfIT) was part of NHS London and had: “…overall responsibility for
upgrading NHS information technology to make it possible for hospitals, community services,
mental health Trusts and GPs to share electronic patient records across the capital”.(93)
When the Department of Health (DH) awarded the LSP contract for London to British
Telecom (BT) in 2003, it was intended to have a single, capital-wide NHS CRS solution. An
initial plan to develop a common solution for both the London and Southern clusters – from
the software supplier IDX Corporation – disintegrated when the Southern cluster LSP
(Fujitsu) replaced IDX with Cerner as its main subcontractor in 2004, followed by BT
terminating its contract with IDX in 2006. BT’s decision in 2006 to replace IDX with the
American supplier company, Cerner, for acute hospital systems in London thus mirrored
Fujitsu’s earlier decision in the Southern cluster. Millennium was already a well-established
healthcare IT system in the USA, and one, large acute Trust in London had independently
chosen to implement Millennium before the start of the Programme.
By 2006, BT had already been working in partnership with Cerner and another supplier,
CSE-Servelec, to give the capital’s acute and mental health Trusts access to greater IT
functionality until the proposed, IDX strategic solution for London became available. They
were focusing on replacing PAS and hospitals’ theatre and maternity systems. The
difference between the interim solutions offered by BT and the awaited strategic solution
was that the latter was to be a single database that was used by all of London’s different
NHS organisations, which would therefore support integrated care pathways in a way in
which the interim solutions could not do.
The delivery of these interim solutions for London’s NHS organisations had been formally
negotiated with the DH in the first major re-set of the London LSP contract, known as a
Change Control Notice (CCN). In a second, major re-set negotiated in 2007, it was proposed
to resolve NHS uncertainties about London’s interim NHS CRS-related IT systems by
formally adopting the use of more than one supplier to achieve shared EHRs. It was labelled
using “best of breed” solutions for the different health sectors in the city (i.e. Millennium for
acute Trusts and RiO for community and mental health) (see Figure 4.3). Under CCN2, there
was to be a London integration engine to route clinical messages from the multiple, clinical
systems supplied through the Programme, and three, major releases of the London
configured Millennium solution for acute Trusts (see Table 4.3). Thus the plan was to deploy
packages (“boxes”) of functionality that built on each other as each subsequent release was
implemented. The second major release, London Configuration 1 (LC1), was to be the first
69
to be NHS Spine compliant – to access patients’ demographic data from the central
database – and to require SmartCard authenticated access by NHS staff.
The interim solution for mental health Trusts (and a different version of the system for
community organisations) was RiO from CSE Healthcare (formerly CSE-Servelec). Unlike
Millennium, RiO is a web-based application and was developed in the UK. RiO
implementations started in London mental health Trusts in 2006, at which time, for the first
time, London was signed up to using the same configuration of the same software in seven
out of the capital’s 10 mental health Trusts. Five Trusts started with an early version of RiO
(version 4.0) and two received version 5.1 as their initial deployment. Version 5 of RiO has
single sign-on SmartCard access and NHS Spine connectivity (see Table 4.4).
BT’s first deployment of LC1 took place in a London Trust in June 2008, and that Trust’s
subsequent, widely publicised difficulties (particularly in relation to activity reporting, which
resulted in the loss of Trust income), led to a “90 day rescue plan”, during which all
Millennium deployments in acute settings in London were put on hold. Similarly, difficulties
encountered by a mental health Trust when it upgraded from RiO version 4 to version 5.1 led
to a temporary suspension of RiO deployments in London until the problems could be
identified and resolved. All deployments subsequently resumed: by 2010, eight mental
health Trusts and six acute Trusts were using these new systems delivered by BT. Two
further acute Trusts had implemented Millennium independently and subsequently joined the
Programme. According to Mr. Kevin Jarrold, head of the LPfIT: “While the acute sector had
proved challenging, the London Programme had achieved significant success with RiO,
which is now in use by all but one of the capital’s 31 primary care Trusts, and eight out of ten
of its mental health Trusts”.(94)
The third set of major contract re-negotiations between BT and the DH began in 2008. The
CCN3 included permitting acute Trusts greater opportunities for local configuration and build
of Millennium systems delivered through the Programme. RiO could be tailored to individual
mental health Trusts by BT in the same way that Millennium could for acute Trusts. The
“new delivery model” proposed in the 2008 negotiations also included giving London Trusts
more flexibility in when they chose to deploy the different functionalities that were potentially
available to them in Millennium, so moving away from predefined, delivery packages of LSP-
bundled releases and edging towards allowing (a degree of) Trust specific “cherry picking”
between release bundles, at least for acute organisations. CCN3 was agreed and signed in
2010.
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The main changes CCN3 brought about were: firstly, it confirmed the new delivery model for
Millennium but this was accompanied by a reduction in the numbers of London deployments
of NHS CRS software systems to acute organisations. These were now to total 15 (instead
of 32 – although precise numbers are liable to change with hospital Trust mergers) by the
end of this contract in 2015. There were also to be enhanced RiO functionalities made
available in two, new versions of the application for mental health Trusts, then to be known
as Release 1 and 2 (replacing the former versions 6 and 7). The total number of these
London RiO deployments was reduced from the originally planned 10 to eight. Provision for
a London-wide integration engine – along with delivery of new systems to London GPs and
the London Ambulance Service – was now out of scope. The revised contract was cheaper;
savings of £112 million – approximately 10% of the initial contract cost - were to be achieved
by agreeing this latest contract, reflecting the DH’s announcement in 2009 that £600 million
had to be pared from the Programme’s overall costs.
Figure 4.3: Structure and components of the London NHS Care Records Service (NHS
CRS) planned for London in 2007 (93) (permission to reproduce in the process of
being applied for)
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Millennium London
Configuration (LC0)
Millennium London
Configuration (LC1)
Millennium London
Configuration (LC2)
• An electronic care record for
every patient
• Patient registration,
admission, discharge, transfer
• Patient medical record
tracking
• Pathology / Radiology
requests, results viewing and
notifications
• Clinical assessments and
documentation
• Scheduling (including
theatres, clinics, beds, diaries)
• Access to management
information and reporting
• Compatibility with Choose
and Book
• Maternity booking of
expectant mothers and recording
of delivery details
• Connection to the Spine (the
national database and
messaging service), providing
access to patient demographic
information, such as name and
address
• Increased security with the
use of SmartCards and single
sign on access to the system
• Theatre case functionality,
including pre and intra
operative documentation, case
tracking views and mandatory
reporting
• Clinical features include
allergies, extended requests,
additional clinical assessments
and ability to link to scanned
documents
• New functionality to
support:
- medication management,
including requesting and
administration of drugs
- anaesthetics, including
device integration
- critical care, including
bedside medical device
integration and critical care
data entry
- advanced structured clinical
documentation
• Enhancements to existing
functionality in the following
areas:
- theatres
-accident and emergency
- requests and results
reporting
- clinical documentation
- patient administration
- operational, clinical and
management reporting
• Future integration with
other care settings
Table 4.3: The three major releases of Millennium f or London acute Trusts, in 2007
(93) (permission to reproduce in the process of bei ng applied for)
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RiO system for mental health Trusts
• Annotated clinical diagrams
• Assessments, to record new assessments and view existing ones
• Bed planning and scheduling, to provide a diary-based graphical
view of current and anticipated activity
• Care planning
• Care Programme Approach review scheduling
• Case record - forms the ‘front sheet’ to the client’s clinical record
• Caseload management
• Clinic management, to set up clinics and create, manage and book appointments
• Diary and planning tools
• Document upload - enables scanned paper assessments, referral letters and other electronic
documents to be attached to the client’s record
• Family links, to allow clients’ records to be linked, where appropriate
• Help function
• Mental Health Act - enables section details to be recorded in line with MHA legislation
• Operational reports - include progress notes by clinical discipline, bed summary reports and
caseload views. The system also produces statutory reports including the Mental Health
Minimum Dataset
• Progress notes, to record a client’s progress, and can be added to and updated by different
team members. Significant notes such as client risks can be flagged, as can those that
contain third party information. Notes that have not been validated can be identified.
• Referral management, to give a chronological list of current and discharged (closed) referrals
Table 4.4: Key features to be offered by the web-ba sed application for mental health
Trusts (95) (permission to reproduce in the process of being applied for)
Rapid roll-out unravels: the South
The Southern cluster presented a distinct story relative to the other two (i.e. London and
NME). It made progress until deployments stalled in 2007 while Fujitsu and the DH tried
unsuccessfully to agree a revised LSP contract, and uncertainties for future deployments for
NHS Trusts continued when the LSP contract was terminated altogether in 2008, leaving the
South with no LSP.
At the outset of NPfIT, the Southern cluster was the largest and perhaps the most unwieldy
of the proposed clusters.(96) In 2006, the three SHAs in the region – South West SHA,
South Central SHA and South East Coast SHA – covered 93 NHS organisations: 31 PCTs,
five Ambulance Trusts, 43 acute Trusts (including 25 Foundation Trusts), 13 mental health
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Trusts, and one care Trust (a limited number of NHS Trusts in England, called care Trusts,
provide both health and social care services).
The contract for the LSP for the South was won by Fujitsu in 2004 and it has been
suggested that this was in part due to their offering a very competitive price.(96) Initially,
Fujitsu was in alliance with the supplier IDX Systems Corporation but early in the contract, in
2005, Fujitsu changed its main software supplier from IDX to Cerner and Millennium
software. This was the start of an ambitious implementation plan in the South, aiming for a
rapid roll-out of a basic version of Millennium (R0) to deliver PAS replacements and other,
limited functionality (initial clinicals, theatres, maternity and A&E), - and then offering
increments of clinical functionality in subsequent releases. The consecutive release, R1, was
to deliver NHS Spine connectivity for Southern Trusts.
Cerner was contracted in part because of the experience of Homerton Hospital in London
with installing Millennium, ahead of NPfIT.(97) However, in this site the software proved to
require significant modification, for example with lost appointment details (see Chapter 6).
Thus delays were caused as significant revisions and amendments had to be made, for
example, to allow new clinical codes and to allow support for Choose and Book (see Chapter
1). This extra work took time out of the release plan and led to Trusts in the South hesitating
and then declining go-live dates
Fujitsu had by July 2007 installed Millennium R0 in eight (approximately 20%) of NHS acute
Trusts in the South; these became known as the ‘Live8’ (see Box 4.2). Progress stalled,
however, as problems with the deployed Millennium systems became more apparent. In May
2008, following lengthy contract negotiations that had aimed to reset the system’s
development and delivery plans – and thereby better meet local NHS organisations’
perceived needs – the DH terminated the Fujitsu LSP contract.(98)
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1. Nuffield Orthopaedic Centre NHS Trust
2. Taunton and Somerset NHS Foundation Trust
3. Winchester and Eastleigh Healthcare NHS Trust
4. Surrey and Sussex Healthcare NHS Trust (99)
5. Weston Area Health NHS Trust
6. Milton Keynes Hospital NHS Foundation Trust
7. Worthing and Southlands Hospitals NHS Trust (subsequently withdrew) (100)
8. Buckinghamshire Hospitals NHS Trust
Box 4.2: The ‘Live8’ Trusts that have installed Mil lennium software
Giving evidence to the Public Accounts Committee (PAC) on why Fujitsu had withdrawn,
Peter Hutchinson, Fujitsu's group director for UK public services said, "We had tried for a
very long period of time to re-set the contract to match what everybody agreed was what the
NHS really needed in terms of the contractual format. In the end the terms the NHS were
willing to agree to we could not have afforded. … There was a limit beyond which we could
not go".(101) Andrew Rollerson, a Fujitsu executive, giving evidence to the House of
Commons PAC said something a little more blunt: "What we are trying to do is run an
enormous programme with the techniques that we are absolutely familiar with for running
small projects. And it isn't working. And it isn't going to work".(49)
After the exit of Fujitsu, NHS CFH negotiated with BT (already implementing Millennium
systems in London as the London LSP) to take over support of the Live8 sites. It was
reported in the media that the price of the contract, and details of how BT would move sites
from the Fujitsu data centre to its own without causing disruption, were critical issues in
these negotiations.(102) Meanwhile Fujitsu was continuing to provide the Live8 sites with
support for the existing implementations.
By 2009, BT was able to take over responsibility for supporting the then seven Trusts with
Millennium in the South (one of the eight had by then withdrawn following its merger with
another NHS organisation).(103) The £500m contract awarded to BT was for a relatively
limited package of work, which included taking over the Live8 Trusts, deploying Millennium
in four additional acute Trusts in the South and delivering RiO to 25 community and mental
health sites.(104;105)
Outside of this contract, acute Trusts in the South were then offered the choice of taking
either Cerner or iSOFT systems, delivered by BT or CSC respectively, or they could choose
75
a different supplier selected from the NHS CFH Additional Supply Capability and Capacity
(ASCC) list.(106)
In 2010, under the BT deal, the DH gave the go ahead for a Millennium upgrade across the
South of England (this had previously stalled over data security concerns with the planned
data transfer from the UK to the US).(107) The Trusts to receive the upgrade were
Buckinghamshire Hospitals NHS Trust, Milton Keynes Hospital NHS Foundation Trust,
Nuffield Orthopaedic Centre NHS Trust, Surrey and Sussex, Taunton and Somerset NHS
Foundation Trust, Weston Area Health NHS Trust Healthcare NHS Trust, and Winchester
and East Leigh Healthcare NHS Trust; local testing of the first technical upgrade stage was
reported as complete in August 2010.(106) Progress had also been made with BT
deployments of RiO in the South. Seventeen out of the 25 sites were live with RiO 5.4 by
August 2010.(106)
4.4.2 What is the NHS CRS?
Our findings have indicated that the NHS CRS was not only the generic name given to a
range of software systems (i.e. Lorenzo, Millennium and RiO), but also a multi-faceted
concept. Different research participants (i.e. managers, healthcare professionals,
administrative staff and patients) attributed a different meaning to the nature and role of the
NHS CRS in secondary healthcare settings. This indicates the lack of a single vision behind
the NHS CRS and the development of multiple interpretations revolving around what the
NHS CRS was perceived to be, what it ended up being and how it could become in the
future. This section outlines these different interpretations (also summarised in Table 4.5)
and argues that the NHS CRS embodies at least three visions: data-centric, process-centric
and policy centric, each with its own aspects.
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Visions of the NHS CRS
Data-centric Business-centric Policy-centric
Digital container of information Computerisation &
Standardisation
Means and outcome of
modernisation
Database that joins-up
healthcare delivery
Business change Means to reinforce existing
policies
Administrative tool Electronic monitoring and
control
Political agenda
Recording device and Auditor Business opportunity Patient-centric tool
Table 4.5: Visions of the NHS CRS
The NHS CRS was conceptualised by participants as a means for digitalising health-related
information, such as patient notes and clinical letters, which was previously held on paper. In
this case, it was envisioned as an electronic container of information that stores, maintains,
updates and disseminates information.(47) In doing so, it was thought to render clinical
information knowable and transferable and to improve the delivery of healthcare to patients:
“Such a fantastic idea to have access to useful clinical information…at the touch of a few
buttons” (Interview, Healthcare Professional, Site R).
Further, interviewees described the NHS CRS as an enabler for sharing information across
temporal and spatial boundaries (this is a long standing aspiration for IT systems, see for
example (108)): “you could go between Leeds and London and not be repeating your same
clinical history was the ultimate goal” (Interview, Local Service Provider). In the view of
clinicians this implied the possibility to exchange information both in an asynchronous and in
an indirect way. Clinicians would then be able to get the necessary information
independently of where they are located. At the same time, they argued that instant access
and transfer of information across hospitals and between general practices and hospitals
would facilitate more “joined-up” processes of healthcare delivery. Electronic joining-up of
healthcare meant for patients that they were no longer responsible for transferring
information across healthcare organisations and between professionals. For clinicians it
meant it would help to improve clinical decision-making by making them less reliant on
patients’ memory and more on accurate and updated facts.
In contrast to this, some participants saw the NHS CRS as a mere administrative tool that
provided demographic information and the possibility to track patients, but had limited clinical
importance: “it’s just a demographic database that doesn’t give me any clinical details”
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(Interview, Healthcare Professional, Site D). In this case, the interviewee identified the NHS
CRS, as a vision, with the system deployed in this particular site.
The NHS CRS was also envisioned by some healthcare professionals as a recording device
and an auditor of clinical outputs. It was thought to constitute, at least in theory, “a very good
audit trail” (Interview, Healthcare Professional, Site C) that made outputs visible,(44)
tractable and amenable to analysis and a means “for monitoring and for reporting and for
performance measures” (Interview, Healthcare Professional, Site M). Clinicians said that this
was not possible before the implementation of NHS CRS systems because data were not
consistently recorded. Yet, participants from Site M argued that although the potential for
monitoring and auditing was there, the functionality was not tailored to their needs.
Also, some participants saw the NHS CRS as a means for computerising and standardising
clinical work practices and processes. Computerisation would render healthcare
professionals’ work paperless: “…if you can get to a paperless system, that is a real selling
point for us” (Interview, Healthcare Professional, Site D) or, paper-light because “there are
some things you have to have on paper, for example, there are things I ask the patient to
draw on like a clock face” (Interview, Healthcare Professional, Site M). Further, clinicians
argued that computerisation would render the delivery of healthcare less reliant on
healthcare professionals (e.g. by populating data) by eliminating errors and data duplication:
“simply by deploying CRS we eliminate all those errors” (Interview, IT Manager, Site D).
Clinicians assumed that computerisation would then allow them to spend more time with
patients. Some patients however expressed their concerns that computerisation, defined
from their perspective as the implication of technology in consultation, would depersonalise
their relationship with doctors.
Some interviewees also perceived the NHS CRS as being a way to eliminate differentiation
of clinical and administrative work practices across Trusts, to standardise the processes of
healthcare delivery and the conduct of healthcare professionals and to regulate the way in
which healthcare professionals interact with patients: “…their ideal is that the NHS will
become standardised, so the way in which we interact with computers and the way in which
we interact with patients will become standardised’ (Interview, IT Manager, Site C). Other
participants welcomed standardisation because they saw it as an opportunity to work in a
“smarter more efficient way” (Interview, Healthcare Professional, Site F).
Apart from computerising and standardising, the NHS CRS was perceived as a means to
initiate business change and improve healthcare service (also found in (44)): “I don’t think
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we are deploying Cerner here, I think what we are doing is reviewing and improving our
services…The core of what we are doing is as a change management programme”
(Interview, IT Manager, Site D).
Further, participants described the NHS CRS as being a means for electronic surveillance
and monitoring of Trusts and healthcare professionals.(109) As they said, the NHS CRS has
the potential (at least in theory) to centralise information about the performance of each
Trust across the country. For instance, through the Spine the DH could potentially have
aggregated information about various performance indicators such as costs, outputs or
performance profiles of each Trust. Centralised information could then be used, according to
participants, as a way to compare the results and performance of healthcare organisations
and as a basis to make decisions. According to one project manager, such comparisons
engendered financial risks and raised fears of job insecurity: “It might give you some
transparencies. It might give you some aggregated understanding. You might find that one
hospital cost profiles are completely different to another. You might start to look at why and
people might be nervous of their jobs, even” (Interview, IT Manager, Site C). In relation to its
electronic monitoring effects and in the context of it holding genetic information, patients
described the NHS CRS as a means for electronic identification of citizens.
The NHS CRS was also presented as an indication of modernisation, a necessity and “a way
of the future” (Interview, Patient, Site H). This was not only because of the availability of
advanced technology, but also because of its potential to improve the old-fashioned ways in
which the NHS works: “I just think the day of paper notes is probably gone when there’s so
much technology around…If you think about it’s a very ancient way of doing things to write
everything down when there’s so much technology out there…” (Interview, Healthcare
Professional, Site H). Through the creation of EHRs, the NHS would be able, according to a
clinician, to respond to the demands of the new generation of patients for instant healthcare-
related information and services: “The new generation wants things now. So waiting for
medical results does not fit with the new generation. In the future patients will expect
immediate results’” (Interview, Healthcare Professional, Site F).
In contrast to this, participants from Site M perceived the NHS CRS not as a means to
change, but as a way to reinforce already existing policies: “You had a policy that you should
have done this. Now, we are just going to reinforce it. That’s what RiO really did. … it does
reinforce the existing policies, which a lot of Trust users don’t follow” (Interview, IT Manager,
Site M).
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Also, because the NHS CRS was implemented during a period of economic and political
turmoil, some participants associated it with an overtly political agenda. This indicated that
the meaning, and more importantly, the existence of the NHS CRS was in flux because it
was shaped by whichever government was in power: “I’ve got a concern that if one of those
two parties come into power and it seems highly likely that they will, that the National
Programme might be closed and Lorenzo might be shut down and what then happens, do
we get left and do we then go back to where we were two years ago, just seems a really
painful situation and do they close the whole of the National Programme in which case, do
we go back to where we were eight years ago?” (Interview, IT Manager, Site C).
Moreover, some participants saw the NHS CRS as being a way for a more patient-centric
healthcare.(110) Through the NHS CRS patients were thought to be uniquely identified
across healthcare organisations: “a patient-centric view looking at it as—one point of
identification single NHS number” (Interview, Healthcare Professional, Site D). Participants
also thought that the NHS CRS gave patients ownership over their record, rendered them
knowledgeable about the information that is included in it and thereby also responsible for its
correctness and completeness: “…it’s the patients that hold the record and the patient
should control who has access to it. …Give the patient the record and give the patient the
key to unlock it. They are partly responsible for the record themselves…” (Interview,
Healthcare Professional, Site R). Also, according to another participant, the NHS CRS would
enable patients to be able not only to access personal health-related information and thus to
participate in clinical decision-making, but also to share this information in other patient
networks.
Patients were however more critical about the assumed patient centricity that lied behind the
NHS CRS. For many, the NHS CRS was primarily a technology-led rather than a patient-led
project. Also, patients expressed their indifference towards computerisation of their records
by arguing that priority should be the quality of treatment they receive rather than the
medium that carries their clinical information: “I am here to get well. I don’t know about what
they do [about records] here and I don’t want to know. It’s their job to look after me”
(Interview, Patient, Site A).
Finally, a healthcare professional envisioned the NHS CRS as a threshold that will attract
more commercial organisations to enter into the NHS. The prerequisite to this was that
clinical processes, pathways and practices become protocolised, represented to the
technology and thus made transferable to other NHS and non-NHS organisations.
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Three points need to be made in relation to the different visions of the NHS CRS. Firstly,
participants dissociated the NHS CRS, as a vision, from the product that was supposed to
embody and deliver this vision. This was despite their concerns about the appropriateness of
the product to achieve benefits in the near future: “Good vision, but whether this system
[Lorenzo] could do it I don’t know” (Interview, Healthcare Professional, Site H).
Secondly, some participants linked the vision with the implementation process of the NHS
CRS. They argued that gradual implementation of the NHS CRS would fade away and
weaken the vision: “…small step changes along the way rather than having a vision of what
they wanted to achieve in the longer-term, so that’s constrained I think, you know, what’s
been achieved” (Interview, IT Manager, Site H).
Thirdly, some participants’ viewpoint that the NHS CRS constituted an administrative rather
than clinical tool may be associated with the limited functionality of NHS CRS software
deployed in many Trusts at the time of our evaluation.
4.4.3 The arrival of the NHS CRS in institutional s ettings
This section reports on the ways in which sites prepared themselves for the arrival of the
NHS CRS. Specifically, it describes the strategies that were set in place in order to embed
NHS CRS systems, and their inscribed assumptions about clinical work and routines,(111) in
the organisations. The process of rendering the NHS CRS a “taken for granted” part of an
institution, i.e. its institutionalisation, was complex and longitudinal.(112;113) As our findings
below demonstrate, it required a clear rationale that was commonly understood and shared
by members across the organisation and robust management and governance structures
that led and oversaw implementation,(113) set milestones and controlled progress. Further,
the institutionalisation of the NHS CRS required a sound technological infrastructure for NHS
CRS systems to work and interface with other systems as well as a clear implementation
strategy for deploying system functionalities. Finally, important aspects of the
institutionalisation of NHS CRS systems were provision of training and security and
availability of resources. Our findings suggest that sites did not manage to fully
institutionalise the NHS CRS but were in different stages of its institutionalisation. The last
sub-section outlines a number of (external and internal) factors that explain why this was the
case.
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Rationale for being ‘early adopter’/implementer of the NHS CRS
As discussed in Chapter 1, at the time of the inception of the NPfIT, all the NHS Trusts were
expected to implement (within specified timelines) the recommended software systems.(9) A
number of Trusts volunteered to become ‘early adopters’ of NHS CRS applications.
Arguably, all the Sites discussed in our report were ‘early adopters’. However, the specific
term ‘early adopter’ was only given to some Trusts and was linked to extra funds provided by
the LSPs. These were the Trusts that piloted NHS CRS software in a clinical environment
and worked with the LSP and the developers to make it fit for clinical use by feeding back
any arising problems. (Refer to Glossary for a more detailed definition). Those Trusts were
promised to receive the Deployment Incentive Fund (DIF), set at different rates, i.e. for
secondary organisations this was £1 million in NME and £300,000 in London. Other Trusts
that were classified as ‘fast followers’ (later referred to as ‘early implementers’) did not
receive DIF (e.g. Site Q). In this report we use the term ‘early adopter’ in a broader sense to
refer to organisations that were amongst the first to implement the NHS CRS systems as
part of the NPfIT.
Although the Sites which volunteered to be ‘early adopters’ had different characteristics and
varied histories (e.g. experiences with IT), the reasons given by the interviewees for being
an ‘early adopter’ were often similar.
Our interviews indicate that an important reason for the Sites to adopt NHS CRS software
systems early was the wish to upgrade their technology without making a considerable
investment. Their existing systems were often seen as lacking some functionalities and as
supporting little integration and communication of data across the Sites and beyond and,
thus, as not fit for the purposes of the NHS CRS. For some, it was a question of comparing
costs of renewing licences for existing systems and the costs of implementing NHS CRS
systems, for which the licence costs did not have to be met by the Trust. The Sites were also
afraid that the support for their legacy systems might be withdrawn by the suppliers in the
near future. For example, one IT Manager in Site C described the NHS CRS as being “an IT
project that’s nice to have” and as an opportunity that “…gets you to a better place with your
IT systems’” (Interview, IT Manager, Site C). This view was echoed by an IT Manager in Site
D: “…having the National Programme funded for us and all the complexities of integration
was obviously a big financial bonus for us” (Interview, IT Manager, Site D).
It appeared that for Site B one of the decisive factors was the DIF: “I’ve got a director of
finance who looks at the bottom line every week and obviously a million pounds coming in
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makes his bottom line look an awful lot better and if he’s off my back that gives me more
freedom to do cleverer things with doctors and nurses” (Interview, IT Manager, Site B).
Hence, it appeared that for some Sites (e.g. Sites B and C), the decision to become ‘early
adopters’ was, at least to some extent, opportunistic.
Another reason given was the wish to influence the final design of the software systems by
adapting system functionalities to their local needs: “…as an early adopter you have a
significant opportunity to shape the development of the product and we’ve been anxious to
do that from a community perspective” (Interview, IT Manager, Site H).
The importance of this factor and the opportunity to work together with clinical reference
groups, other implementer sites, NHS CFH and local SHAs was highlighted by the decision
of Site Q to remain one of the first to implement Lorenzo, despite that it did not receive the
DIF, as it was not classified as an ‘early adopter’, but as a ‘fast follower’.
The sites also anticipated a number of organisational benefits, including:
• Easier meeting of business objectives and governmental targets e.g. ‘Clinical Five’
(114)
• Efficiency gains as a result of a better process management and of elimination of
maintenance costs coming from dispersed systems
• Improved sharing of information with other NHS organisations and social services
• Increased recording and availability of information at the point of care
• Improvement in data quality.
Some participants expressed a hope that the benefits of being ‘early adopters’ would help
their Site to gain competitive advantage over other sites. Sites hoped that early participation
would be seen as “leading” and “forward thinking”, and hence that their status and prestige
would be enhanced: “I think we were attracted by the kudos of being the first, well OK we’ll
be the first. And there was something to celebrate when, well actually [name of other site]
and [name of other site] are not on yet and it’s just us, well there’s just us, there’s nobody
else” (Interview, IT Manager, Site H).
Another important factor in Sites’ decision to implement the NHS CRS was their prior
experiences of implementing information systems (for instance, Sites A, B and E had
experienced staff). Participants believed that ‘early adopters’ were fundamentally different to
other sites in that they had greater experience in IT implementation, were forward thinking
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and innovative. They would also present themselves as having a strong vision, persistence
and established working relationships with other key players (i.e. IT implementation teams,
LSPs and NHS CFH). This illustrates a parallel underestimation of the complexity of
implementing NHS CRS systems and an initial, perhaps naïve, confidence about their
capability to implement and adopt it in an unproblematic way.
However, the decisions to become ‘early adopters’ were not uncontroversial or uniformly
supported. For example, in Site C participants mentioned two reasons to reject early
adoption: the lack of a clear business driver behind the NHS CRS and the lack of user
enthusiasm. Participants from Site R, for example, argued that being an ‘early adopter’ was
not a choice, but a decision made at SHA level: “…our SHA chose two sites to be the first
adopters of Cerner… From the Trust perspective it felt very much it was decision outside of
their control” (Interview, IT Manager, Site R). Similarly, in Site D the majority of users
described the Millennium software as an imposed standard application for acute Trusts in
London: “I think you have to take the view that there was almost no choice in taking on the
system, but you would try and make the system more usable with time” (Interview,
Healthcare Professional, Site D).
Furthermore it appeared that at the time of making the decision the sites were not aware
how much development work they would be expected to do. Some also suggested that the
decision to implement was not based on knowledge of “what the real benefits are” (Interview,
Healthcare Professional, Site R).
Management and technical infrastructures
‘Early adopter’ sites set up project management teams responsible for orchestrating,
supervising and managing the implementation of the NHS CRS. Teams varied substantially
in terms of number, skills and expertise but in general terms they consisted of: Programme
and Project Managers (e.g. for Infrastructure and Data Migration, Clinical Documentation
etc), Training Leads, Business Change Leads, Configuration and Testing Leads, Data and
Business Continuity Leads, Product Specialists and Clinical Leads. Implementation team
members were often sub-contracted from within the Trust, NHS CFH, LSPs or from other
organisations.
Implementation teams operated within broader governance structures that monitored and
made decisions about implementation processes. Governance structures consisted of
Programme Steering Groups, responsible for monitoring the delivery of the NHS CRS in
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sites, Project Management Teams, responsible for carrying out implementation on a daily
basis, and Clinical Advisory Groups, responsible for advising the Programme Board about
clinical issues that surround NHS CRS adoption.
The role of SHAs, NHS CFH and LSPs in this broader structure was fundamental.
Specifically, the role of the SHAs was to support sites in the management of the project by
providing a link between LSPs and NHS CFH, helping to sign off key deliverables (e.g.
testing and training) and providing links with other relevant stakeholders in the local health
community including other ‘early adopters’. The role of the NHS CFH was to manage
contracts with LSPs, provide support to the implementations that took place in ‘early adopter’
sites and mediate between sites and other organisations (e.g. LSPs). LSPs managed
implementations on a day-to-day basis by setting milestones and monitoring progress,
resolving emerging issues and managing risks in collaboration with software developers.
Robust project management structures and experienced leadership were described as being
key to a successful NHS CRS implementation (see the case studies of Sites D and Q).
Strong leadership required personal and face-to-face contact with the users and involvement
in users’ work practices (see the case study of Site Q). This type of participative leadership
allowed managers, as they argued, to better represent users’ needs and requests in front of
other parties (such as LSPs, software developers and senior implementation members) and
to give users the sense of being listened to (see the case studies of Sites H and Q): “…we
do encourage them to, for it to become a two way communication, it’s not just us talking at
them but equally if there’s anything that they don’t understand because in project terms you
do tend to speak in project jargon which is not all the time, you know, good with clinical staff”
(Interview, IT Manager, Site Q).
Also, leadership was important for accommodating the NHS CRS into the organisation and
for bringing together its operational and its technological aspects (See the case study of Site
D). It was also thought to make implementation an imperative and “a priority project”
(Interview, Healthcare Professional, Site F) for sites. A lack of such communication was
perceived as problematic (see the case study of Site B) and as a reason for failure and a
top-down leadership style would often create a pressurised environment that influenced
healthcare professionals’ morale (see, for example, the case study of Site Q).
Apart from leadership at a top level, participants thought that middle-level managers, such
as divisional managers, played an important role in fostering implementation at local level
and engaging clinicians. A representative from an SHA argued that this is because middle
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managers have better control over local practices: “…middle managers which they often
have more control, I suppose for want of a better word, they are able to do that more
effectively for a number of reasons–they seem to work better” (Interview, SHA).
According to the NPfIT Infrastructure Compliance Standards and Guidelines,(115) ‘early
adopter’ sites needed to have a specific infrastructure in place before implementing. This
included:
• Hardware: routers, modems and networking products, desktops, printers, scanners,
handhelds, trolleys, RAM to upgrade any existing PCs, bandwidth to speed up
connections, or other components
• Software system (Lorenzo, Millennium, RiO etc)
• SmartCards and SmartCard readers
• NHS Net email accounts.
Implementation strategies: approaches and methodolo gies
Sites followed a number of different methodologies for implementing NHS CRS software
solutions, which are summarised in Table 4.6. As we show below, in many cases Trusts
from the same cluster would follow the same methodology, but would name it in a different
way due to the different rationales and expectations of it.
To begin with sites in the NME implemented Lorenzo gradually as it was not an existing
product, but was developed whilst being implemented. Gradual implementation meant that
sites would implement different functionalities of each release incrementally.
Implementation Strategies Rationale
‘Soft landing’ Identification of problems at an early stage
Deal with past negative experiences from IT projects Small scale approach
Preventative strategy: reduce risks & achieve results
Stepwise implementation Interdependent functionalities
Contractual restrictions & limited autonomy ‘Big-bang’
Core aspect of their IT strategy & a means for joining-up their
operations
Prior preparatory work to render the organisation ready for
implementation
Phased, but fast implementation
Geographical criteria – meeting the purposes of the London
Mental Health Trusts Team
Table 4.6: NHS CRS implementation strategies
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Specifically, Site B decided to go for what they called a ‘soft landing’ approach which
introduced change gradually into selected locations. Participants agreed that this strategy
allowed them to get used to the system slowly and help to identify and tackle emerging
problems. This strategy was characterised by a parallel running of both paper and computer
systems; for some staff though ‘soft landing’ did not constitute technically a “proper go-live”.
Sites C and H went for what they called a “small scale approach” to implementation.
Implementation team members from Site C believed that this approach was more
appropriate because of the size of the project and also due to their (negative) past
experiences in implementing IT systems. Participants from Site H thought that a small scale
approach would reduce risks as Lorenzo was not ready for large-scale deployment (Site H).
The logic that governed this implementation process was that the system would be
introduced across the site gradually only after it brought about satisfactory results to its first
area of implementation: “Once we get to a known stage that’s, where it’s all usable and it’s
all reliable we can then put the whole service on...” (Interview, IT Manager, Site H).
Site Q followed a ‘stepwise’ implementation because CSC could not support two releases at
any one time and due to technical dependencies (e.g. PAS functionality had to precede Care
Plan functionality). They were however aware that a soft launch approach may add
considerable delays to the implementation process.
Some Cerner sites implemented NHS CRS software systems on a big scale. Specifically,
Site R followed a ‘big-bang’ approach to their implementation of Millennium. Initially, they
implemented a different system provided by the same supplier (Fujitsu) but within four weeks
changed to Millennium due to contractual re-arrangements. In a joint discussion with two IT
Managers it was explained that the Trust did not have an implementation decision to make
as “…clearly the system was given to us, so it wasn’t a question of picking and choosing and
selecting the system for those benefits. There were elements of functionality that we could
choose to ignore” (Interview, IT Manager, Site R).
Sites D and E also decided to implement the NHS CRS by following a ‘big-bang’ approach.
They rendered Millennium a core part of their IT strategy and joined-up all their operations
around it. With a similar rationale, Site F went for a ‘big-bang’ approach aiming to eliminate
their existing dispersed systems and substitute them with a single coherent system across
the Site.
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Site BB followed a phased, but fast (in terms of adopting upgrades of the product)
implementation of RiO. The main reason for this was that the implementation team members
had done a lot of preparatory work in getting the organisation ready for Millennium, but then
after Fujitsu left the Programme and due to problems with the system (i.e. lack of mental
health functionality), they switched to RiO. They planned then to implement fast sequential
upgrades of the product. The same strategy was also followed by Site M, which as a part of
other London mental health Trusts, went for a fast two-phased (initially three-phased)
implementation based on geographical rather than functional criteria.
NHS CRS implementations were carried out using PRINCE 2 Methodology,(116) which
involved the following stages:
1. Preparation (e.g. vision, business case, organisational readiness assessment)
2. Initiation – (training, interfaces, work process changes, PID etc.)
3. Local design – (testing configured solution and revise plan if necessary) (see 4.2.4.)
4. Preparing for go-live – (testing and finalising the solution, approval to proceed (ATP)
5. Go-live
6. Support (deployment verification period (DVP), Trust taking over)
7. Project closure (lessons learnt and review).
The preparation stage was intended to render organisations ready for the implementation.
Two of the most significant stages in this process were explanation and diffusion of the
vision behind the NHS CRS implementation and mapping out of existing work processes. In
relation to the vision sites focused on presenting to implementers and users the need for
change and the anticipated benefits from the NHS CRS. In doing so they would achieve
engagement and would ensure that the system: “…it’s not seen as a system coming in for
the sake of implementing a system but it’s, we want to change the way we work and that’s
just a tool that’s brought it on the back end to assist in that process’” (Interview, IT Manager,
Site H).
Another important part of preparation was to map out existing business processes. The aim
of this was to represent current processes and then decide on how these would be
reproduced and embedded into the system (e.g. Site D) or redesigned to fit into the system
(e.g. Site R, E) or a combination of both (e.g. Site F). An important aspect of this process
was clinicians’ involvement, since on many occasions implementation team members lacked
knowledge about clinical practices. Yet, clinical input was often perceived to be lacking (see
the case studies of Sites C and Q). Further, our data suggest that some sites did not map
out what it is that clinicians were doing on the ground (the actual clinical practices), but
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focused on what they should be doing based on protocols. In this way, they limited the
potential of the system to reflect clinicians’ work.
Key aspect of the initiation stage was integration of existing systems. Most sites ran a
number of different computer systems across specialties and departments that had to be
integrated during NHS CRS implementation. System integration aimed to achieve
consistency of data across systems and required technologies, such as integration engines
and other components that would link together the Spine, the NHS CRS software and sites’
different systems. Integration also presupposed data cleansing, which ensured that data
were up-to-date, and data migration from existing systems into NHS CRS software. Some
participants however reported that despite technologies that were put in place data
discrepancies between the PAS system and NHS CRS software still occurred.
The communication process between the Sites, LSPs, SHAs and NHS CFH had a significant
impact on the implementation process. Sites met on a regular basis with LSPs in order to
discuss previous and planned activities, assess risks and set milestones, to monitor
progress and to manage issues related to software customisation (for more details about this
collaboration see Section 4.4.4 Configuration versus Customisation of the NHS CRS
software). Further, Trusts were responsible for developing communication strategies in order
to inform future and current users of developments in relation to the NPfIT (see, for example,
the case study of Site H). This intended to eliminate silo mentality and enable more joint
working (see the case study of Site Q).
Training
Assistance for users of NHS CRS systems was delivered through formal training and on-
hand support during the first weeks of use. Each Trust organised their own training in order
to tailor it to the local systems and the needs of users. They deployed their own trainers, who
themselves received training on the system from their LSP (CSC and BT). Often, the scale
of training was considerable (for example, in Trust B 3,500 users were trained).
Training was primarily focused on teaching functionality of the software, and in some cases
included an assessment of the staff IT skills and an introduction to basic IT-skills (e.g. in Site
C). Initially, training on new NHS CRS systems tended to be generic, and sometimes on
training systems that differed from the go-live system, but approaches to training evolved
(e.g. in Site A). In Site M, training went beyond teaching narrowly understood IT-skills (e.g.
ability to use a mouse, keyboard, word processor, email or some other software) and
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included sessions on information governance, clinical governance and the Data Protection
Act. Also, despite initially having fairly generic training approaches, most the sites over time,
to a greater or lesser degree, attempted to relate the training to different needs of different
professional groups and to focus on the use of the software within a context of their work
practices. This usually was achieved by a small role-based group training sessions. For
example, in Site D, following training and one week prior to go-live, more than 600 workflow
familiarisation sessions for staff from different disciplines took place. These were individual
face-to-face sessions conducted by champion users as well as clinical leads who had
received special training and were used to the software. The aim was to familiarise the staff
with the NHS CRS and its effects on their work practices.
Overall, the sites employed some or all of the following forms of training:
• Classroom-based lectures to raise awareness (although these tended to be done in
individual work places)
• Workflow familiarisation or “process map” sessions for different users, including
champion users and clinical leads explaining how the software systems might effect
users’ work practices, small group training (often in role-based groups)
• One-to-one support from clinical leads and peers
• Interactive demonstrations of the system over the intranet
• Refresher training (needed due to the delayed ‘go-live’ dates but also required after
the implementation and the initial use)
• Performance assessments
• Paper and online materials, as well as e-learning environments.
Training was linked to evaluation and access to the system. For example, in Site M trainees
undertook an exercise driven evaluation based on practical scenarios related to a patient
journey. Users were only granted access to the system and issued with SmartCards upon
completion of training.
Opinions regarding the experience of training varied from very negative to decisively
positive. In all the sites users felt that support from trained individuals within their own team
was most valuable: “I’ve found that going and sitting down next to somebody and spending
time and saying this is what you’re doing, this is how you use it has probably been more
helpful because they’ve been able to say oh yeah and they’ve done it at the time” (Interview,
Healthcare Professional, Site Q)
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A common complaint was that the training was too early and the material was forgotten by
the time it was needed to be put into use, which was inevitable given frequent postponing of
go-live dates, which was usually beyond Trusts’ control. In some instances, staff were
trained and ready for imminent go-live only for the planned deployment to be put on hold
(e.g. Site A). Other criticisms included concerns that training was ‘”not sufficient” and
“rushed”. In some Trusts, users felt that the training “was way too broad based and too
generic and it missed a point” (Interview, Healthcare Professional, Site D) and that it “didn’t
focus precisely on the bits of the system that we had to use and was not about the actual
workflow that we would be doing” (Interview, Healthcare Professional, Site D). This was
echoed in Site M: “I didn’t think it was useful for what we needed to know to be able to do
our jobs. […] It didn’t tie in our processes and it didn’t tie in sort of PIs [performance
indicators]’” (Interview, IT Manager, Site M). Some participants (in Sites Q and B) mentioned
that they missed the opportunity to “play around with the system” in a safe environment,
without being afraid of making mistakes on a live system.
On the other hand, in Site C, training was well-received by users on the grounds that it was
focused, detailed and ongoing: “…we were really well supported and it was training on the
ground. And in fairness, I think that’s probably the better part of Lorenzo experience…. It
wasn’t just a training session, go away and do it was real-time with real patients and that I
think was really helpful” (Interview, Healthcare Professional, Site C). Similarly, users were
generally satisfied with the training in Site H. However, both Trusts embarked on small-scale
implementations, and such a level of one-to-one training and support might not be
sustainable in large-scale implementations.
Despite an overall positive user experience of the training in Site C, a nurse reported that the
training missed an important aspect, which was users’ education on EHRs. She said users
lacked good understanding of what Lorenzo meant and what it could deliver, a vital part of e-
literacy in the healthcare setting. A similar view was conveyed by a consultant: “I think that
they understanding of Lorenzo by us, as clinicians is not good. I think we need to
understand. I think perhaps we ought to have better education about it, rather than being
involved in setting it up, I think perhaps what we should have had is education about what it
meant. What the outcome might be and what imprint we needed to do and how we might
understand how the system actually works, that would have been useful. I also think Lorenzo
needed some better understanding about the clinical processes that they are supporting with
this, so I think there was a bit of a balance with that” (Interview, Healthcare Professional, Site
C).
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IT teams and trainers acknowledged that it was difficult to organise training. They
encountered at least some of the following problems: a difficulty with engaging professionals,
especially consultants, due to their busy work schedules, different e-literacy levels, the
training environment not reflecting the live system, changing go-live dates and as a result
training often running months before the actual go-live date. For example, in Site B 3,500
staff were trained in 10 weeks on R1.9, but when the go-live date was postponed they all
needed refresher courses. However, even without the additional problem of postponed go-
live date the sheer scale of the training needs posed great challenges. Hospitals cannot be
closed for staff training days and hence all frontline staff cannot attend training lessons at the
same time (near the go-live date). The scale of the training and support required (particularly
in a Trust-wide implementation) and the implications on resources was a source of real
concern. For example, Site D deployed almost 70 floorwalkers on the wards for three to six
weeks after go-live. In addition, in Site C an IT manager argued that there was limited
interest coming from the Trust and the SHA in terms of how training was organised,
delivered and received, stating that “the problem I have is that training is the last thing that
anyone thinks of. […]. It’s always an afterthought” (Interview, IT Manager, Site C).
Often trainers had to be flexible and adapt to the needs of busy users, providing
individualised one-to-one training sessions at the individuals’ place of work, as the following
quotes illustrate: “…we do have a medic who has a very busy role, hasn’t had a chance to
go on the training yet and so I need to look at potential different ways of engaging them in
getting them trained so that they can go onto the system. And then I’ve got another one that
it’s taken them probably two months to get it but I did, I’ve organised so she could have
individualised training, she does have disabilities so she did need additional support so what
I’ve done again I’ve arranged for one to one and that happened earlier this week but it meant
a trainer actually going to the service whereas most of the training has been done in our IT
suites and that’” (Interview, IT Manager Site Q).
In summary, the key messages from the Trusts about the content and delivery of training
were:
• Training should take place as close to the ”go-live” date as possible, ideally no later
than a week before (but this is rarely achievable) with refresher sessions and
sessions for new people run as needed.
• It has to be delivered when and where the users need it (i.e. at the most convenient
time, if necessary in small chunks and not far from their work place).
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• A realistic environment that feels like “live system” and is populated with data, which
can be safely manipulated, should be used. Users should be able to access the
training environment to “play with it” after training sessions.
• A mix of different methods (e.g. classroom/group/individual training, manuals and
other supporting documents and e-learning) might be offered. However, support from
peers (e.g. super users) was considered as most beneficial.
• Training should be focused and specific to the user role but at the minimum it needs
to include an introduction to the whole system, providing users with an understanding
of the system and its implications for their (and others) work.
• It is important to cultivate good relationships between trainers and staff.
• Some participants spoke of the need for early involvement of the training team with
representatives from different care settings (e.g. in business change workshops) or
even for the co-production of the training with doctors and IT people working
together.
• Some participants also believed that training should be provided in small groups and
accompanied by standard operating procedures (SOP) before the go-live date
An important overriding message was that the training strategy needs to be as flexible as
possible, i.e. opportunistic, changing with the circumstances, e.g. different for different
releases and tailored to diverse users’ needs. Training is an ongoing process, and plans for
training new staff (in particular rotating junior doctors) need to be in place. However, our
findings suggested that no amount of formal training, however well-run, will remove the need
for hands on, one-to-one and preferably peer-based support. This may also involve drawing
on experienced users from more experienced Trusts, particularly during the first weeks of
go-live.
Availability of resources
Sufficient resources (human and financial resources) were necessary for the timely
implementation of the NHS CRS: “If we can get enough resources we can certainly, you
know, make their goals but if we don’t we never will” (Interview, IT Manager, Site B). For
Trusts that were part of the NPfIT Local Ownership Programme (NLOP) resources were
estimated by the Resource Manager. Participants though felt that this estimation was not
pragmatic because it drew upon the amount of resources spent on previous implementations
of different software solutions.
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‘Early adopter’ sites received financial incentives in order to implement the NHS CRS. These
resources were spent on training, equipment and manpower (e.g. sub-contractors to help
with project management). Participants were concerned that the Programme had limited
budget to cover all their expenses adequately and that certain components they would like to
implement in the future wouldn’t be possible to be implemented: “… they’ll say well we’ve
run out of money we can’t, you know, can’t keep, the project can’t keep the contractors any
longer so we’ll just wrap it all up and we’ll never achieve what I know we can achieve”
(Interview, IT Manager, Site H). Long-term implementation costs were thus planned to be
covered by individual Trusts.
Apart from financial resources a substantial number of people were required to carry out the
implementation process. These included trainers, business change leads and local
champions. In many cases, extra manpower such as floorwalkers and product specialists
were provided by LSPs and locums were employed (Sites H and D) to compensate for the
time healthcare professionals devoted to learn the system. Some Trusts (e.g. Sites A and M)
were concerned about the costs of bringing in external knowledge and expertise and about
how to transfer and develop such capabilities internally.
Concerning human resources, one of the most fundamental problems that some ‘early
adopters’ had, was the fact that some members of the implementation team were working on
contracts. Contracts were created in order to ensure that competent and dedicated people
worked on the project. Indeed, implementation team members would often bring experience
from commercial organisations, some were even ex-employees of the LSPs or suppliers
(Site A, C and Q), or had previously implemented the same system elsewhere (e.g., Site M),
which enabled a better work relationship between the commercial organisations and Trusts
(Site Q).
Some contractors tended to have a fairly narrow focus on implementing NHS CRS software
into organisations, resulting in a relatively narrow perspective on the NHS CRS. They
perceived it as an internal project that had to be successfully carried out rather than a
national project with long-term consequences on both the Trust and the community it serves:
“I was given a project initiation document, team of resources and asked to implement…I’m a
contractor …I’m brought in to do a job. My job is to put this system in for XXX. I have a focus
that is Site C Centric and that’s what I aim to do. Do I spend time belonging to an associated
and an affiliated body that’s bigger and wider? For the greater good I’d probably do. That’s
not my main focus” (Interview, IT Manager, Site C). However, for others, it was precisely an
appreciation of the “bigger picture” that characterised the work of contractors as they had
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insights into the wider implementation landscape beyond the organisation they currently
worked in.
Contracts often ended during implementation, and contractors would leave the project taking
with them all the knowledge they had accumulated. Apart from loss of knowledge, the
termination of contracts slowed down implementation processes and reduced
implementation teams’ enthusiasm and morale to continue with the implementation process:
“Well they’ve told him that’s the end of his contract. I mean how long do you continue to
support a pilot, and I don’t want to carry on unless we’ve got somebody like [Name] that is as
keen and as switched on and as knowledgeable” (Interview, Healthcare Professional, Site
H).
Also, changes in key implementation team members (Site Q) was thought to slow the speed
of implementation.
Concerns related to the arrival of the NHS CRS in i nstitutional settings
The arrival of the NHS CRS in institutional settings was influenced by a number of factors
which are outlined and presented in Table 4.7 below.
Delays in organisational readiness due to intra-Trust differentiation
Parallel running of other initiatives and projects
Implementation dissociated from actual practice
Complex supply and management chain
Limited resources
Changing NHS policies
Table 4.7: Concerns related to the arrival of the N HS CRS
Delays in rendering institutions ready were related to substantial differences among
departments and wards concerning their attributes, business processes, existing technical
infrastructures and level of computerisation. For instance, Trusts that were mainly paper-
based required a major cultural change to shift to a largely computer-based mode of working
in comparison to Trusts that ran computer systems before the introduction of the NHS CRS
and thus switched to it faster.
Also, the management and implementation of the NHS CRS had to be aligned with local
business strategies. In Site M managers prioritised the NHS CRS initiative over others so as
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to take it forward in a faster and more effective way. By contrast, Site B kept various projects
running in parallel adding in this way delays in the implementation of the NHS CRS.
It has also been reported that both local and national management of NHS CRS
implementation was often perceived as being dissociated from the actual deployment of the
system and from the day-to-day reality of clinical practices: “They put no thought into the
nitty gritty and how clinical teams will use it and so with regard to long-term vision, I can see
what they see is a lovely neat system where we are all using computers. That was a very
superficial view. To run RiO properly and the success of RiO depends on the clinicians. They
needed to come down a few layers and get people working with the clinicians from day one’”
(Interview, Healthcare Professional, Site M).
Similarly, the programme and a senior manager of Site R argued that the LSP often set
contractual milestones that were hard to be achieved within the timeline. This conditioned a
pressurised environment for implementation team members and healthcare professionals to
work within: “The milestones in the plan were set as a contractual milestone so we weren’t
allowed to alter those. What was quite difficult was we had to work backwards from those
milestones. … milestones that were set were probably going to be unachievable, but we had
to work within the constraints of that contract” (Interview, IT Manager, Site R).
Further, a complex supply and management chain that was adopted for the delivery and
implementation of NHS CRS systems resulted in convoluted communications and delays
(e.g. Sites B and C). Specifically, LSPs and NHS CFH, including LPfIT, were sometimes
viewed as links in the communication chain that hindered responsiveness to Trusts and
implementation progress: “…it takes much longer to do anything than you think it’s going to
take and there’s so many people involved, so many committees involved to get anything
done at the supply side that it takes a long time to get things sorted and that’s unfortunate”
(Interview, IT Manager, Site H). Further, participants from Site M were concerned about the
contractual obligations of each party that was involved in the supply chain, mainly because
core aspects of their work, such as reporting, were not supported by the functionalities
embodied in RiO: “Reporting was one of the things that were omitted. It’s something that
maybe [LSP] or not [LSP], LPfIT should have done” (Interview, IT Manager, Site M).
There were also concerns about the commercial nature of LSPs, which led to a prioritisation
(rationing) of the support they provided to ‘early adopter’ sites especially in the post go-live
periods. For instance, it was reported that CSC would withdraw support for a site
(independently of their stage of implementation) in order to focus on the highest political
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profile or the next go-live site. Similarly, Fujitsu (when it was still the LSP in the South) would
prioritise next go-live and fast implementer sites independently of the importance of the
issues that other sites encountered and raised: “Where you were in the plan determined how
quickly you got out to supplier resources and that was definitely obvious. That is the
downside of the National Programme, isn’t it? They will always put the focus on the early
sites” (Interview, IT Manager, Site R).
It was also repeatedly highlighted that the management of the implementation processes
was influenced by limited available resources. The latter created a pressurised environment
for implementation teams and conditioned uncertainties concerning future implementation.
As an SHA representative said: “There is little money around and I think that people are very
concerned…” (Interview, SHA).
The management of the NHS CRS was also influenced by changing policies of the NHS. It
has been reported that changes in policy bring about changes in the planning and
management of implementation: “I mean if you think about the history with the NHS starting
back in 1948, it’s never stopped changing, so when is it ever going to stop changing, you
know, you can kind of use that as sort of like when is this ever going to end, perhaps when
the NHS actually comes to an end then because until then the NHS will always change.”
(Interview, IT Manager, Site Q).
Finally, some participants were concerned about the limited understanding that
implementation team members (and in some instances NHS CFH staff) had about the
requirements (e.g. technological infrastructure, training) of the NHS CRS initiative,
particularly in rendering the organisation ready for its adoption, and the extent of
organisational and cultural change they would need to go through. These reasons made
some participants from Site M argue that perhaps a slower approach to NHS CRS
implementation would allow them to prepare better, make better usage of available
resources and attract and maintain key and supportive people. On the other hand, with a
phased implementation of EHRs, users might not see some of the early benefits as systems
are initially not integrated.
4.4.4 Working-out technology-led change – instituti onal, professional and ‘everyday’
narratives of change
In undertaking this study we have been concerned to explore the implementation and
adoption of software systems to support the NHS CRS from a variety of perspectives – to tell
various people’s stories (even of things). In particular, and reflected in this section, we have
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been concerned with the clinical users of these systems. What they have experienced, how
they perceive the potential and the actuality of such systems, and how they can incorporate
them into their work practice with advantage for them, for patient care and for the healthcare
organisation.
The limits of ‘Implementation’ as discrete change
Change implies a shift from one situation to another. It assumes that comparisons between
‘past and present’, ‘before and after’ or ‘here and there’ are possible and indeed desirable so
that change becomes manifested. A focus on change however, cannot reveal the actual
process of change (the internal and ongoing ‘how’) or the complex drivers of changing or not
changing (the ‘why’).(90) Furthermore, change is seldom a rapid or direct movement from
‘the old’ to ‘the new’, rather the new is born within the old and co-exists with it, and the old
and the older still remain present (albeit often in different forms) within the most
new.(54;117) Change, seen from this perspective, is then a process surrounded by
continuities and discontinuities of ways of acting and thinking.
For the above reasons we argue and show below that implementation of the NHS CRS is a
process that was made to work through the mediation of a number of people and
technologies.(44) This process was conditioned not solely on predefined visions and
strategies but primarily on relationships, processes and practices as they emerged on the
surface. It also conditioned a number of intended and unintended consequences that were
likely to give rise to new clinical practices and procedures or to reproduce or modify the
existing ones. We have adopted a process-based approach to study the implementation of
the NHS CRS that focused on exploring and interpreting this process of change rather than
evaluating it as either ‘successful’ or ‘failed’. On the basis of the above and in line with our
sociotechnical ontology we make the following three assumptions concerning NHS CRS
implementation.(50)
Firstly, people and technology are co-constitutive because actions and their effects cannot
exist without the involvement of both people and technologies.(54;117;118) Secondly, the
introduction of a technology in a healthcare setting requires considerable ‘configuration’,
‘translation’ and ‘appropriation’ before being embedded into healthcare settings.(33;39;45)
As we show, NHS CRS software systems had to be adapted in order to meet the needs of
the hospitals within which it was introduced (configuration) and had to be constantly
interpreted and modified (translation) in order to become meaningful to the users
(appropriation). By focusing on these aspects we also captured the use, non-use and ‘mis-
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use’ of the NHS CRS not as positive and negative effects of its implementation but rather as
some of its necessary conditions.(119)
Thirdly, the NHS CRS products were neither totally malleable nor fixed but were being used
in ways that reconciled the assumptions embedded in them with the clinical practices and
pathways that prevailed in healthcare settings.(109;120) In this way, the NHS CRS
implementation is conceptualised as a process that cuts across boundaries (institutional,
professional etc) in order to be made to work.
Implementation versus adoption
NHS CRS software systems (or their customisations) were built and implemented while in
use, i.e. while the system was being ‘adopted’. Especially for Lorenzo, intended to be built
while in use, this nature of a ‘continuous implementation’ process was (and at the time of
writing will be), “like painting the Forth Road Bridge” (Interview, IT Manager, Site B).
Furthermore, deployment did not necessarily result in use of the software systems, making
the technical, ‘official’, go-live date, “as most of the [IT] world would recognise it”, different
from the ‘real’ go-live stage in practice: “… the hard landing for us was, I mean the soft
landing was the technical go-live, the hard landing is a go-live as most of the world will
recognize it in that people were using the system” (Interview, IT Manager, Site B).
In the NHS CRS, and especially in the case of Lorenzo, the distinction between
implementation and adoption is blurred; rather the software systems were being put into use,
used and adapted and back to being ‘implemented’. A cyclical, process of growth, that in
order to ‘progress’, also displayed signs of ‘regression’, as a Lorenzo Implementation Team
member explained: “Every time you get a new build you sometimes get some regression,
you sometimes get, things break you know, they broke photo upload at one point. Little
things like that or things don’t, they change things and assume it’ll be alright and it isn’t
alright so…” (Interview, IT Manager, Site H).
However, this cyclical process of building and using - implementation and adoption- clashed
with the rigidity of a structured approach with a focus on documentation: “Everything has to
be specified, everything has to be written down, when it comes back it has to be multiply
tested, it has to be fitted into a framework, it has to be assessed against every other national
service, I’m surprised they get anything to be honest.” (Interview, Developer)
This structured approach, summed to a multiplicity of layers and stakeholders
(‘implementers’, from NHS Trusts, LSPs, NHS CFH, etc.) between users’ feedback and
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‘programmers’, resulted in a very slow process of software systems’ improvement (and users
feeling not being listened to). When components of the software systems were
built/developed in a cyclical mode with a relatively fast turnaround (e.g. Site H), adoption
seemed more successful. Nonetheless, there was potentially a tension between users
feeling disengaged from a readymade product such as Millennium and users being
motivated and able to give their time to participating in system development and build, as in
Lorenzo.
Each system (or build) implementation, release or roll-out, was then part of a lengthy and
laborious processes of adoption. Direct and indirect users of the NHS CRS, initially at times
sceptically hosting this new intruder in their daily life,(121) came eventually to appreciate
and/or refuse it. These processes of adoption at times had unexpected endings. For
instance, in Site H, healthcare professionals initially only used Lorenzo because it was
mandated, but they made it work for them, only to face losing the system for another one to
be introduced in its place. This was a collective achievement, with the support of a dedicated
IT manager,(122) for the role of ‘special people’ in systems implementations). Finally their
efforts were placed into not “let [their Lorenzo] die”, a definite measure of ‘success’ for this
implementation: “So what we’re doing at the moment is just trying not to let it die, […], we’re
trying to show that it still works, […], I’m trying to talk to commissioners to try and try and get
them onboard […] They’re looking at two systems, they’re looking at [xxx] and they’re
looking at [yyy] and somebody much higher than me will make a decision” (Interview,
Healthcare Professional, Site H).
In other contexts, the attempted adoption was less successful, with abrupt cut-off points (Site
R), or a feared slow ‘death’, a “death by a thousand cuts” as intended users slowly stop
using the system: “…the individual, each person working on the project across every Trust,
across every sector, you know, if morale is low, if there’s a perception that it’s going to get
canned in six months anyway so why bother, you know, it’s death by a thousand cuts…”
(Interview, IT Manager, Site B).
The following sections will provide further insight into these processes of adoption and
change.
Configuration vs. customisation of the NHS CRS soft ware systems
Unless an EHR system is developed locally in the healthcare setting where it is supposed to
be used (‘home-grown’ system),(23) ‘off-the shelf’ systems require some degree of
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configuration or customisation. For the purposes of this report we define configuration as
being the process of fine-tuning and customisation as being the process of redesigning
software (code and subsequent upgrades) in order to meet local needs. Table 4.8 illustrates
these two approaches along with the processes that participant sites followed and their
results. Processes of configuration and customisation indicate that technology is a physical
entity embodied with particular characteristics and built on certain assumptions that require
negotiations before being used.(123) Data from our research indicate that different NHS
CRS software systems were modified in secondary healthcare settings in different ways.
Specifically, Lorenzo ‘early adopter’ sites would customise the software, as it did not exist as
a final product, whereas Millennium and RiO sites would configure it within the limits of their
contract.
Lorenzo had to be substantially developed and redesigned by ‘early adopter’ sites in order to
meet their needs and clinical processes. ‘Early adopter’ sites would get new builds of the
system on a regular basis and test them in the testing environment before they went live to
the live environment. During this process they collected any issues that emerged either from
the testing or from the actual use of each build. These issues were then prioritised and kept
by each ‘early adopter’ site in a log and were collectively managed by ‘early adopter’ sites,
NHS CFH, CSC and SHA through what they called the Issue Management Process (IMP).
These issues would be reported to CSC, which would then report them to iSOFT in order to
be fixed. The process however was not as smooth as presented here.
Often sites would get upgrades that were close to but not exactly what they requested or
upgrades that looked like ‘nothing they had specified’ or new releases that fixed issues but
undid past changes, allowing in that way reoccurrence of the same issues (what they called
regression) or rise of other issues. Also, they would often get builds with delay, for instance
in Site H implementation team members had to wait for over a year for an issue to get
resolved, leaving limited time for testing or upgrades. It has also been reported that changes
were often delivered in very small chunks, which meant that users felt they were left with a
‘half-finished solution’. Most importantly, many times issues were not approved as such by
CSC and NHS CFH on the grounds that the software met the specification and worked as
designed.
To enable the IMP some project team members of the Lorenzo Early Adopter Programme
(LEAP) travelled to Chennai and worked together with the developers in order to fix some
bugs of the system whereas iSOFT and the LSP set up regular web-conference meetings
with ‘early adopter’ sites during which the software was demoed from Chennai and sites
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were able to comment and provide feedback before any change was made to the code. NHS
CFH and the SHA also appointed “form builders” located in the UK in order to speedup
customisation.
In Site R configuration of Millennium was managed in a similar way. The problems they
encountered during the testing of Millennium were discussed internally and then prioritised
before being reported by the Trust to the LSP (Fujitsu) in order to be fixed. Participants
though reported that the version of the system they were implementing (version zero) was
“…relatively inflexible…”, that they “…had to push hard for every single change in the
system…” and that “finding solutions seemed to be long winded and difficult” (Interview,
Healthcare Professional, Site R). Further, the site would on some occasions disagree with
the LSP about the importance of some of the issues that were raised which meant that some
of the issues would either be resolved with delay or not resolved at all.
Indeed, many issues that were raised remained unresolved on the grounds that either the
software met the requirements, and thus worked as was requested, or a requested change
was not a part of the contract, and thus could not be made. Further, the site was given a
limited timeframe to implement with potential financial penalties for failing to meet these
deadlines, adding further problems to configuration. An SHA representative further argued
that one of the obstacles in this configuration was that the site did not sufficiently understand
the scale of changes (in clinical work and process) they would have to make. Some of these
problems were addressed albeit at later stages of implementation when people from Cerner
worked directly with implementer sites from the Southern cluster.
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Configuration/Customisation Process Result
Customisation Redesigning the software to match
clinical processes (NME sites)
Still under development
Partial success
Fine-tuning constrained by
contractual limitations, strict
deadlines and financial penalties
(Site R, BB).
Stopped implementation
went back to their old
system (Site R).
Chose another system
that supports mental
health functionality (Site
BB)
Fine-tuning of the product and the
code (Sites D, E & M)
Minimal changes in the
product to meet needs.
Fast deployment.
Configuration
‘Anglicisation’: reengineering of
clinical process in parallel with
software adaptation (Site F)
Preparation for go-live in
May 2011
Table 4.8: Configuration versus customisation of NH S CRS systems
In contrast to this, Sites D and E implemented the so-called New Delivery Model of
Millennium which allowed implementation team members to configure the product to their
needs. The site configured “probably less than 2% of the system” (Interview, IT Manager,
Site D). The product was changed at two levels: change in the code which would occur
every two years and configuration of the product which was delivered in a more timely way.
The site configured the product by working closely together with BT and Cerner on site. Co-
location was perceived as an important factor for accomplishing joined-up configuration,
avoiding bottlenecks in the supply chain and dealing with failures directly. This process also
gave the site a sense of control over configuration although the LSP would still play an active
role by mediating between the site and Cerner.
Similarly, Site M configured RiO in order to meet the needs of clinicians. Specifically,
participants argued that the functionalities embedded in RiO did not support reporting on
performance and thus brought in people to help develop this functionality.
Site F in the Southern cluster configured Millennium with the University Pittsburgh Medical
Centre (UPMC) with a view to ‘anglicising’ the software (originally a US system) so that it
represented their clinical pathways and reflected their lines of accountability and hierarchy.
Anglicisation, as participants explained, meant comparing what the system offered with the
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Trust’s clinical processes and making necessary changes and innovations. The purpose of
the Trust was neither to redesign the software nor to adapt existing practices to fit into it but
rather to critically look into clinical processes and improve them by using the available tools.
This required extensive collaboration between clinical groups and the IT implementation
team as well as between the Trust, Cerner and UPMC.
Implementation team members from Site BB that initially implemented Millennium
abandoned their attempt after a few years due to the substantial amount of time they spent
on configuring the software to match mental health settings and processes. Major factor for
this was that mental health functionalities, although incorporated in Millennium, were not
purchased in the contract. Participants raised a number of concerns during configuration and
customisation, which are summarised and presented in Table 4.9.
Concerns surrounding customization and configuratio n processes
Concerns Implications
Normative concerns:
• dissociation from central purpose
• branching of the code
Standardisation vs. Localisation
Concerns related to:
• differentiations between Trusts
• differentiations between clinical work
• common needs for similar information
• differentiation as manifestation of
professionalism
Lack of Knowledge about:
the product
the English NHS
clinical work
Systems not reflecting work practices and
business processes of NHS organisations;
conditioning critical safety issues and demanding
substantial changes in clinical work practices
Complex supply chain Mediation required significant translation of the
messages being exchanged between
organisations
Involvement of commercial organisations (LSPs) Prioritisation of product delivery and its outcomes
over quality of product and processes of
configuration/customisation
Table 4.9: Concerns surrounding customisation and c onfiguration processes and
their Implications
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Firstly, some participants raised normative concerns in terms of whether the software should
be customised and configured (or not). Their argument was that the conventional purpose
behind the NHS CRS is to have a national contract and similarly a nationally shared solution.
Thus, the more localised the software becomes the more distant it gets from its centrally
defined purposes: “If you keep giving people the ability to localise things you kind of drive
away from a centralised understanding…” (Interview, Healthcare Professional, Site C). Also,
localisation assumes deep changes in the code of the product, what a participant from Site H
described as ‘branching of the code’, that makes it rigid for national use.
Also, there was a dispute among participants concerning the extent to which clinical
processes can be standardised or not. Some people argued that hospitals work in different
ways, have cultural differences (e.g. Teaching Trusts, Foundation Trusts etc) and often
different care processes for the same healthcare problem: “…it’s all different everywhere you
go, they do things differently and they all think their way is the best…” (Interview, Healthcare
Professional, Site H). For instance, mental health professionals have a very different way of
recording data, most of the times by dictating, their data is in the form of a narrative, and
they tend to work across a number of settings both within and outside Trusts (such as
patients’ home). Further, differences in the amount of financial and human resources that
sites have at their disposal, variations in the types of contact clinicians have with patients
and variation in health population conditions differ in the ways in which Trusts work. Because
of these differences technology needs to be flexible and customisable in order to meet
everyone’s needs.(110)
Others, however, supported the view that healthcare professionals need the same type of
information (such as patient demographics, diagnosis, treatment, GP details and clinical
letters) to carry out their clinical processes and that ‘90% of the processes can be
standardised across Trusts’, implying that a common product would be an effective solution
for all current ‘early adopter’ and future sites. Indeed, RiO was implemented in 8 out of 10
mental health Trusts in the London cluster bringing a number of benefits to the Trusts such
as sharing experiences and learning as well as economies of scale. This, as participants
from Site M reported, was despite the fear of loss of autonomy when it came to important
decisions about configuration and deployment of RiO.
An SHA representative also said that often healthcare professionals emphasise their
differentiation because of their professional power: “…to a large extent, medics kind of
doctors have control to a large extent over what goes on in the Trust and they are very
powerful and they like to do it their way…. They easily circumvent the situation and they are
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able to do that, because they just say, you can’t question my professional judgment”
(Interview, SHA).
Many people also advocated that the NHS CRS would need a similar base-code that is
nationally shared but configurable to local needs.
Secondly, an obstacle to configuration was the limited knowledge that ‘early adopter’ sites
had about the software. Lorenzo was since the point of its adoption, under continuous
development. CSC was not in a position to provide full demonstration of Lorenzo and
consequently, implementation team members did not seem to know what it is exactly they
are implementing: “I haven’t even seen R2, I haven’t even had a chance to play with R2 so I
don’t even know what it does I just know what I’m told it does. Every time I ask to be able to
get my hands on it and play with it and just see how it all works there’s always reasons why
that can’t be done…” (Interview, IT Manager, Site H). Similarly, sites in the southern cluster
(Sites R and BB) had either limited or no understanding about what the product was or how
it would function in their Trust. Some implementation team members thought that this was
deliberately done because the more the sites are aware of the software the more likely it
becomes that they would request for changes to be made to the software
Thirdly, software companies and service providers had limited knowledge about the clinical
practices and processes NHS CRS systems were supposed to support.(39) Software
developers and providers were not knowledgeable about how the English NHS works and
about its distinctive nature from both other industries (such as commercial organisations)
and other national health systems (such as the American health system). As two managers
from a Southern site said: “I think there were problems in terms of their view of how the
system worked which was based on their knowledge of the American NHS or the American
healthcare processes” (Interview, IT Manager, Site R). These differences had to do with
“…how they would call certain things, some issues had to do with semantics, some issues
had to do with who does what, the flexibility that goes with each system, some things had to
do with the different pathways” (Interview, Healthcare Professional, Site F). As a result, the
system reflected developers’ perceptions of clinical processes, often as being linear and
homogeneous, but not the actual complexities that surround clinical practices:(109) “…what
was delivered was a clumsy system that seems to have been designed for one clinician who
has clinics booked up in advance that uniquely come in and everybody who comes shows
up or maybe they don’t show up. There is nothing more complicated than that” (Interview,
Healthcare Professional, Site M).
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The mismatch between perceptions of and actual clinical practices would often lead to builds
that raised clinical safety issues or demanded substantial changes in clinical work practices.
For example, managers from the Southern cluster explained that they had to educate their
users to the new language embodied in the system, such as Emergency Department (ED)
rather than Accident and Emergency (A&E) and the different clinical pathways. For this
reason, clinicians and members of the implementation team had to interpret the initial design
before translating it in a way that reflected clinical practice.
A fourth concern was the lack of direct communication and contractual relation between
implementer Trusts and software companies. This mediated, by LSPs, communication made
it difficult to exchange messages that are interpreted in the same way by all the involved
parties. As an SHA representative argued: “We were hearing things from the NHS … third
hand as it went from Cerner to Fujitsu to us. A lot of times when things weren’t quite right
and when things were not explained to us correctly, and, not through any malice at all, but
just because they didn’t understand it either and it wasn’t explained” (Interview, SHA). This
complex supply chain has been characterised by participants as a “cumbersome process…a
chain of command” (Interview, Healthcare Professional, Site C) and a “Chinese whisper
situation” (Interview, IT Manager, Site C). Also, the lack of a direct contractual relation meant
that they had “to fight for every single change” (Interview, Healthcare Professional, Site C)
and “had to keep pushing for them” (Interview, IT Manager, Site Q). An illustrating example
is when participants from Site H threatened to pull out of the process.
Finally, participants raised concerns about the consequences that the involvement of
commercial organisations brought about to the quality of the software and thus to the level of
its customisation and/or configuration. Specifically, they argued that contracts were focused
on the delivery of the product rather than on its quality, process of delivery and
consequences of its implementation: “I think it’s always very difficult when you involve a
commercial company with a public service, because a commercial company will always be
driven by profit and the money that they are making. Maybe as things get critical the quality
of what’s delivered becomes a secondary issue.” (Interview, Healthcare Professional, Site
C). Implementers of the Southern cluster also argued that the contract incorporated an
‘unachievable plan’ and constrained the configurability of the software adding problems not
only to implementer Trusts but also to the LSP: “…the contract was set out for the South, it
constrained not just us but probably the supplier as well in terms of us putting workable
solutions in locally” (Interview, IT Manager, Site R).
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Work processes, changes in work practices
The NHS CRS as a technology-led change programme was intended to change work
practices towards making patient care safer, standardised, more effective and
efficient.(15;124;125) This section focuses on the changing of work and work processes for
clinicians, clerks and other front-line staff. Though the unfolding of the Programme also led
to changing practices for other staff members, such as for instance, the NHS Trusts’
managers, and local IT helpdesks (for instance: the existing IT support services within Trust
B had to be restructured, covering for a national service desk too removed from the local
needs; Site M took the opportunity to develop a help desk software to improve their
services).
As each implementation was different – different organisations, of different sizes, with
different geographical distributions, different legacy software systems and IT infrastructures,
skill mix, work processes, histories, visions for change and NHS CRS technology deployed –
findings vary across sites. Some recurrent themes emerged from the case studies. They are
presented under the two headings of changes to ‘clinical and administrative work processes
for patient care’ and ‘local management processes’ for clinicians’ role as local managers or
service leads. A summary of the themes is presented in Table 4.10.
Type of work Aspects of changing
practices
Issues and characteristics of aspects
of change
Use of the NHS CRS as ‘part of the job’
Time constraints and wasting resources
Team-working
A variety of ‘users’ and reasons
to use the systems
Direct use/data entry versus use of the
data for secondary purposes
Time for change
Software systems usability problems,
technical issues and disruptions
Adapting the software or adapting to the
software
Workarounds for work coordination,
waiting for full roll-out
Processes of adaptation,
compensating, workarounds
Workarounds to ‘trick the system’ and ‘get
the job done’
The myth of the paperless practice?
Clinical and
administrative work
processes for
patient care
Changes to sequencing in
recording clinical notes Concurrent note-taking when with the
patient
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Retrospective data entry, after patient
care
The myth of ‘speeding things up’? Redistribution of work and time
for patient care Redistribution of data entry workload
Information access and retrieval
processes
Legibility of written information
Saving time
Real-time data
The affordances of ‘being digital’
Critical mass
Hardware and Infrastructures
Remote work
Flexibility and mobility of work
Wireless work
Frustrations Quality of work life
Satisfactions
Direct use of reporting systems
Data warehouses and time-lags
Managing with real-time data
Time for managing
Accountability and Trust
Professionals’ profile and costing
Local management
processes
(clinicians as
managers) Making work visible
Changing relationships and team-working
Table 4.10: Changes to work processes and work prac tices
Clinical and administrative work processes for pati ent care
A variety of ‘users’ and reasons to use the systems
Across all implementations, the main clinical users of NHS CRS software systems were
administrative staff (e.g. ward clerks), junior doctors, nurses, matrons and allied healthcare
professionals (AHP – e.g. podiatrists, mental health therapists, psychologists). NHS staff
tended to accept the use of the NHS CRS software system as ‘part of the job’ as they were
asked to do so by their Managers: “…to me it’s just something that I’ve been asked to do, so
I do it” (Interview, Healthcare Professional, Site H).
Senior doctors – consultants – more rarely engaged with the system on a daily basis. For
instance, in Site M, a consultant psychiatrist explained the junior doctor would type the
information on RiO: “I have a team. I probably use [RiO] less than 10% of the time, because
if I’m seeing patients in a ward setting, it would be my junior doctor that’s inputting the
information…” (Interview, Healthcare Professional, Site M)
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In Site BB, consultants were mandated to enter progress notes in RiO, but they then
returned to their previous practice of dictating notes for their secretaries to type: “…as a
Trust, we mandated the fact that [consultants] have to put their progress notes in to avoid
any delay, because of best practice. We did that with all of them, but we actually went back
and checked, […] the majority of those consultants in Phase 1 we’re doing it. Now we are
onto Phase 6 and we are hearing through the grapevine and suddenly they are dictating
those and the admin are now entering the progress notes on their behalf, as a separate to
the dictation of letters which may take, you know, three to four weeks to come through”
(Interview, Healthcare Professional, Site BB).
Pre-existing work practices allowed junior clinical staff to perform tasks on behalf of
consultants (team-working). But NHS CRS software systems and access-control technology
at times mandated data entry to senior clinicians, and this was seen as conflicting with the
required flexibility of team-working: “The thing with ICD [International Classification of
Diseases] in coding is, it has to be a consultant that puts it in [RiO] and can’t even be a junior
doctor, so that’s just slightly irritating to me” (Interview, Healthcare Professional, Site M).
Some consultants objected to use of the system and argued for their junior doctors or admin
staff to use it. For instance in Site Q, psychiatrists argued for, and obtained, administrative
support for typing notes, as this would impinge on their clinical time and would be a “waste of
resources”. However, NHS CRS systems were also implemented with the support of senior
consultants (e.g. in Sites C and E NHS CRS systems were implemented because of a
consultant motivation).
Consultants and service leads showed a greater interest and use of reporting functionalities
and data available through the software systems, to inform and manage the services they
lead (more on this in the following pages).
Processes of adaptation, compensating, workarounds
In some cases users were asked to use a system that was perceived as not ready, and/or
required duplication of work on parallel systems, was cumbersome, had slow response time,
was time-consuming, at times stressful and frustrating. Getting the NHS CRS system to work
initially required so much attention that they felt they were “spending more time with this
system than we were actually with the patient” (Interview, Healthcare Professional, Site H).
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In sites where the NHS CRS system replaced an existing PAS, problems with data migration
resulted in over- or under-booked clinics, information missing in the system etc., with major
disruptions in the running of services and “fundamental effects on coordinated activity (as it
informs both patients and clinicians where they need to be at any point in time)” (Researcher
Field Notes, Site B).
Yet, despite a feeling that the NHS CRS was making their traditional job more cumbersome,
NHS staff generally kept using it as they felt they had to (and they still are at the time of
writing). In some cases, interface design and system functionalities were viewed as having
considerably improved in the two years since Lorenzo was first introduced “the difference
was much more noticeable …the number of clicks and the speed as well…” (Interview,
Healthcare Professional, Site H). In some cases there was a perceived lack of improvement.
In other cases with time, users got better at using the system they were given. The software
systems were made to work through a process of adoption and adaptation: if the technology
could not (or would not) be changed to fit the existing work process (and if the new work
process as intended could not be made to work), the work process needed to be adapted to
accommodate the idiosyncrasies of the technology. Getting to know the limits of the
technology, clinicians learned to prepare and compensate (for instance for the slowness of
the system, logging in well before the arrival of the patient in the clinic (Site H)).
Workarounds abounded.(126) For instance, keeping the paper record as the shared, official,
patient record and printing off from the NHS CRS system the information recorded in it. In
the words of an IT manager, printing the record is the ‘biggest workaround’: “… you see so
one of the workarounds would be the print. I mean that’s the biggest workaround isn’t it at
the moment that they’re printing off and putting it in the case notes […], but it’s temporary
until they’ve rolled out the rest of the functionality within it, isn’t it?” (Interview, IT Manager,
Site Q)
The most common ‘workaround’ involved the use of paper (printouts, post-it notes, diaries,
etc) as a reminder of activities or for coordination of work. Some workarounds, such as
printing the record, related to the more general workflow, and were due, for instance, to the
need to share the record with users currently not on the system (other healthcare
professionals in Site H) or with other paper records (e.g. other radiology requests from wards
not using Lorenzo, in Sites B and C); others were ‘creatively’ devised to overcome usability
issues with the technology, such as taking screenshots of the just-typed notes when the
system “froze”, and printing it to add it to the paper file, to avoid having to re-do time-
consuming work. The need to “trick the system’” in order to overcome constraints and “get
the job done” (e.g. mandated fields/screens unfit to a specific clinical activity (Site Q), or
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absence of the right clinical code in a drop-down menu (Site H)) resulted in issues further
down the line, for instance, impacting on data quality or management’s ability to monitor
activity levels (see also data quality section).
Changes to sequencing in recording clinical notes
The major change in work practice that was expected of the NHS CRS was concurrent entry
of clinical information on the system at the time the activity takes place (e.g. when consulting
with a patient). For instance in Site D, management intention was for “staff to update the
record in real-time, so that CRS became accepted as a normal part of their work” (Interview,
IT Manager, Site D). Most EHR implementations are based on this implicit assumption, that
EPR would enable a paperless practice, though more than once this assumption has proved
to be false. In the case of the NHS CRS, for the majority of Trusts clinicians did not enter
data in the system while they were with the patients (either at bedside, during ward rounds,
or during outpatient clinics). The example of mental health patients presenting in A&E was
particularly telling: “I think there is a big issue for junior doctors out of hours and the
nightshift in A&E because what the psychiatric assessments are quite lengthy and there is
quite a lot of notes that go with it. What they usually do while they are in with the patient is,
they make the notes as they go along and they are the record. They’ve raised concerns that
they will be in with the patient and they are then going to have to come and type those notes
up. They are not going to be able to do it while they are with the patient, because of issues
like risk. These are patients that are really quite disturbed. You can’t kind of be faffing
around getting them by computers. So it’s going to increase the time spent and you are then
delayed seeing the next patient, that’s going to impact on the breaches of A&E which is I
think the big anxiety” (Interview, Healthcare Professional, Site M).
At times the context of use clashed with using NHS CRS software for concurrent note-taking.
For example, during a new patient assessment with an elderly patient who had hearing
problems, the patient could not hear the clinician sitting away at the desktop computer (Site
H); using a laptop when assessing a patient’s wound could be similarly challenging and a
clinician suggested that working in a team could offer a solution: “Yeah, you know, stuff that I
get over my lap with a patient you wouldn’t want anywhere near a computer, you know,
particularly in the high risk clinics, you know, there’s a lot of mess and different things you’re
doing. I think it works better as well in the high risk clinics when there’s two of us working
together because if I’ve got a wound and I’m getting all messy because I’m dealing with a
wound then, you know, I measure it and I can’t go suddenly to the computer to put in a
measurement, you’ve got your gloves and you’re covered in everything, you can’t do that…”
(Interview, Healthcare Professional, Site H).
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Concurrent notes, if any, were still taken on paper and sometimes written up from memory
hours after the care activity had taken place. But the need and requirement to record data in
the NHS CRS software system led to a change to sequencing in recording clinical notes.
Data entry into Lorenzo was most usually done retrospectively, sometimes days after the
clinical encounter, raising safety as well as efficiency concerns3. In using Millennium,
clinicians in Trust D decided to limit their use of the software system to requests and
reporting, but to keep annotating clinical notes and diagnosis on paper for the same safety
and efficiency reasons: “…Of course people don’t have the time to do that, because you
might have to see seven patients on a ward and you can’t be whisking between a patient
and a computer all the time, because you’d have to do it in between each patient. If you start
doing it at the end of the round people would start forgetting and then you might put the
wrong information into the wrong set of notes. Then you are going to have increasing errors,
which if they are clinical can have significant consequences” (Interview, Healthcare
Professional, Site D).
Redistribution of data entry work and time for patient care
Although some Trusts (e.g. Trust D) had to increase the number of their administrative staff,
at least temporarily, to make the NHS CRS software work, computerisation also generally
led to a redistribution of work, with clinicians doing more of the data entry that would
otherwise be done by ‘typists’ or ‘data entry’ clerks. The NHS CRS software systems were
originally intended to reduce clinicians’ administrative workload and in some cases (Lorenzo,
but also a non-NHS CRS system such as the Electronic Discharge Summary in Trust P were
presented to the clinicians as ways to ‘speed things up’. However, it is well known that data
entry at the computer often takes longer than on paper, so for instance in Trust H, outpatient
clinics were given 5-10 more minutes to have time to access and complete the electronic
patient record (Lorenzo). But no similar provisions were made across all settings, for
instance in Trust D: “All our doctors and nurses are having to work harder now, because we
are having to see the same number of patients with less time, because you are spending
more time on a computer now and we have got no more doctor or nursing resources to do
that” (Interview, Healthcare Professional, Site D).
Having information already typed in the system by the clinician at the point of care (versus
having to wait for a typist to complete it) and the real-time electronic transmission of
3 Implementation teams were looking into hardware as a potential solution (laptops, voice recognition
software and digital pens). But it may not be just a matter of hardware?
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messages (such as Requests and Reporting, Referrals, Discharge Summaries) can make
the activity in its entirety collectively faster, though part of the work has been redistributed at
the point of data entry. A participant, from Trust D, explained this shift, with a comparison
between paper and digital requests for tests and investigations: “I use [Millennium] only to
request lab tests and X-rays - I have no choice in that - but when I work at peripheral sites, I
save a lot of time as I can there use 'old fashioned' paper request forms which are very
much quicker to complete albeit that the process is then presumably slower for someone in
the labs or imaging department.” (Interview, Healthcare Professional, Site D)
The affordances of being digital, and changes in information access and retrieval
Computerisation of previously paper-based practices brought benefits associated with the
positive affordances4 of ‘being digital’ (see (127) for a comparison of positive and negative
affordances of paper and computerised written information). For instance computerisation
made written information legible. As a nurse pointed out, the problem with illegible
handwriting was ‘across the board’: “The main thing really is that we can read people’s
writing. That was a big thing before that you couldn’t actually read what people were writing
in the NHS across the board. Now we can read everybody’s writing. That is a major thing.
And people I think forget that over time. You quickly forget the bad old days of not being able
to read what somebody has written or reading traditionally, they say doctor’s entries, but it
was everybody” (Interview, Healthcare Professional, Site M).
It also made more (if not all) clinical and activity information available digitally (anytime,
anywhere, given access with the right SmartCard). The more successful NHS CRS systems
implementations saw the benefits of having all information at hand, by saving time and effort
by not having to have to “route through drawers for notes and constantly try and find patients
notes and queries and stuff” (Interview, Healthcare Professional, Site H). Similarly, for
finding information within the record, RiO facilitated information retrieval by searching and
filtering: “... If you are going, wanting to find something, you will be able to find it much more
easily. If you think I want to find the entry that I know the psychologist made, rather than
hump through, you can just filter by psychology and you are going to be able to find things
much more easily” (Interview, Healthcare Professional, Site M).
4 The term ‘affordance’ was coined by James Gibson (1977) to refer to “what [the environment] offers
the animal, what it provides or furnishes, either for good or ill”. The term is often used in relation to
computerised systems to refer to what people can use the systems for (positive affordances), or the
systems constraints (negative affordances), the quality of the systems, its benefits or disbenefits
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Clinical information in RiO was seen as ‘live’, ‘secure’ and ‘accessible from clinicians’ desk’,
and the benefit of having real-time access to the notes was felt across the board: “I think the
uniform response by the benefits of RiO and using RiO at the moment is everybody saying
the same. It’s the kind of speed and ease of access to client notes there and then, the data
is live. It’s secure and we can access it from our desk. From the ward and anywhere in the
Trust that if we need that information. That is quite uniform in the Trust” (Interview,
Healthcare Professional, Site M).
However, this benefit of computerisation only really materialised after the software system
use reached a ‘critical mass’ of users and data. One site reported that the use of the
software system, both for managers and clinicians on the ground, became really meaningful
only with use. Initially one had to ‘feed the beast’ (Site H), getting very little, if anything, in
return.
Increasing flexibility and mobility of work
In the changing process, there are continuities and discontinuities of practice (see also for
instance, the case of Trust C). Thanks to the infrastructure put in place for NHS CRS, users
were now computerised and connected and this enabled more flexible and mobile work. For
instance, mental health clinicians in Trust BB, “if they are at home and they finished in A&E
they don’t come back to finish writing up their notes and do it at home” (Interview, Healthcare
Professional, Site BB). Clinicians then were able to work remotely, exchanged information
across settings (see section on working across boundaries) and more flexibly and efficiently
attended to patient care. For instance: “…a patient from this particular clinic needed to be
seen as an emergency the week before, we couldn’t fit them in till this Tuesday so I arranged
for them to go to another clinic and I was able to access their records on Tuesday so I could
actually see what had happened to them on the Friday. Now that wouldn’t normally
happen , I would know they’d gone to another clinic but I wouldn’t know any more than that
probably so that was good and I like to be able to do that just to click on that patient, see that
they have gone to another clinic, what had happened and I’d got that information in front of
me. So I like the fact that I can access the information” (Interview, Healthcare Professional,
Site H).
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Changing quality of working life
Despite the fact that Lorenzo is one system, its design and functionalities are different in the
different settings and possibly with a different combination of hardware and network
infrastructures. While the healthcare professionals in Trust H made it work for them,
changing their work practices for the better, and even eventually transformed their practice
into an (almost) paperless practice, for other Lorenzo users, the system seemed to have
made their work practices ‘worse’ (see case study of Trust B) and, at the time of writing,
were still experiencing the frustrations usually only encountered at the initial stages, when
learning and getting used to a new system. Coping with NHS CRS implementations over a
long period of time (e.g. 12-18 months), had (and at the time of writing are still having) an
effect on the quality of people’s workdays, for better or worse. In Trusts B and Q, because of
the additional workload linked with the use of the technology, and no extra support, one of
the medical secretaries had to go “off with stress”, staff were found “in tears”, people started
“looking for other jobs”. The stress was particularly apparent amongst administrative staff,
seeing work piling up and the system (or its configuration, or combination of hardware and
network) “taking 2 or 3 times as long” (Interview, Administrative Staff, Site B). Clinicians are
also “driven mad” but they did have the option of not using the system: “I fill about 5% of
Lorenzo in and the other 95% just doesn’t get done because I just emotionally can’t bear to
try to do it cause after 15 minutes I just want to throw the computer out the window, it drives
me mad so I just don’t do it” (Interview, Healthcare Professional, Site Q).
Similar frustrations were experiences with Millennium implementations. For instance in Trust
D, clinicians and admin staff experienced frustrations and a sense of embarrassment for the
created inefficiencies: “There have been inexcusable problems with booking patients initial
and follow-up appointments. …. Appointments are often sent out to close to the day of the
appt, so pts don't get them. They are therefore discharged and have to go back to the GP to
start the whole process over again. …. The system seems to be geared primarily to
collecting payments and not providing a patient friendly service. The level of service we are
able to provide is embarrassingly poorer than pre CRS - this is very demoralising. Having
worked in private practice, there is no way you would send a patient back to their GP to
trigger the next step in the pathway should they have discharged SOS” (Interview,
Healthcare Professional, Site D).
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Clinicians as managers and changing local managemen t processes
Managing with real-time data
One of the “business change elements” of NHS CRS implementations was connected to
being able to manage teams and services on the basis of real-time activity data, captured
during clinical work processes. The reporting functionality of Lorenzo was highly valued
amongst managers. Though not all CRS software systems gave direct access to clinicians or
service leads to real-time data, as ‘reporting functionalities’ were not included in their initial
releases. For instance, in RiO: “Reporting was one of the things that were omitted [from the
contracts]” (Interview, IT Manager, Site M). However, while reporting problems experienced
post-deployment could reflect NHS CRS functionality, they could also reflect problematic
underlying organisational processes that became exposed when the new system came into
use or overly optimistic expectations of the system, or a combination of these.
In cases without reporting functionality, clinicians interested in extracting activity and/or
clinical data relied on the Trust central data warehouse and information analysts’
intermediation, with an inevitable time-lag: “We are struggling now a little bit as to how we
can monitor that. Because we can’t get a live report from our reporting warehouse. If the
data is on a Monday, it’s three days out of date. It’s already too late. There is no point”
(Interview, IT Manager, Site M).
With funds from DH and assistance from Cerner and BT, Trust D embarked on an ambitious
project to build its own data warehouse extracting data from the Millennium software and
various other systems including a financial system. The vision was “that data warehouse will
be a Foundation for all other Trusts, because we are developing the data warehouse for the
NHS in London, really” (Interview, IT Manager, Site D). However, at the time, users criticised
its limited reporting functionality: “I think one of the biggest things I find frustrating is the
report element. It seems to be in a warehouse, somewhere. It’s like very little I can see
access to be able to go into the system and pull off something you need” (Interview,
Healthcare Professional, Site D).
More information, more time needed for managing
If entering data on the system requires more time for clinicians (than annotating on paper),
also making use of this data requires more time on the part of managers: “I have better
access to the quality of care. There is nowhere to hide with RiO. If you didn’t put something
down, it’s going to be missing and you can see straightaway. When you do an assessment
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it’s logged. I go well, why didn’t you do the risk assessment? It’s much easier to manage,
you would think. It takes more time to manage” (Interview, IT Manager, Site M).
Making work visible
Digital activity-data made people’s work visible, and this enabled service managers to bring
service adjustments and monitor performance of individual members of staff. For instance, in
Trust C, a consultant of the Radiology department argued that Lorenzo brought about
visibility to their work by allowing them to know who is responsible for each of the electronic
requests they receive. In Trust H, being able to see each others’ caseload and ‘risk level’,
motivated AHP to improve their practices and ensure they would record activity on the
system so that it would show up in the reports: “It’s good for performance management as
well, so you can go back to clinicians and go OK never mind how many patients you saw this
is your risk level of your case load, this is the risk level of somebody else’s caseload, look at
the difference? Why do you think that might be and you can also look at numbers, you know,
this is the number of letters that you’ve sent to GPs how come so and so sends this many
letters and you only do this many letters, you know, because you’ve got absolutely
everything there.” (Interview, IT Manager, Site H)
The process led to changes in team-working, for instance, towards a fairer distribution of
work among the team members. A Lead Nurse in Site M suggested that this transparency is
changing relationships: “I think it would change our relationship. I think it’s more transparent.
I have more Trust in them [my staff] because I can see everything there are doing”
(Interview, Healthcare Professional, Site M).
Making work visible was one the reasons for supporting the NHS CRS among a variety of
stakeholders, for instance ‘to raise the profile’ of their profession, and justify the cost of
services. For instance, in Site H, the Service Lead felt that being able to access this
information would raise the profile of their service and that it would facilitate getting access to
financial resources: “And that was another opportunity with Lorenzo to raise the profile of
[the service] to show everybody that this is what we do, we don’t do that, that and that but
we […] you know, we do extend people’s lives and quality of life and this was a way of
actually proving it. Because one of these days the commissioners are going to turn round to
me and say why should I pay you £600,000 a year […], so I was looking for some activity
information that was a bit more detailed, a bit more quality information” (Interview,
Healthcare Professional, Site H).
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4.4.5 Data quality
This section discusses the respondents’ perceptions of data quality and potential
implications of work processes and changing work practices on data quality. Data quality
was identified as one of the potential benefits of the NHS CRS in the national policy and in
the Trusts’ documents; hence it is discussed separately here.
Data quality is described as “the state of completeness, validity, consistency, timeliness and
accuracy that makes data appropriate for the purpose intended".(14) Other commonly used
categories of desirable attributes (or dimensions) of data include accuracy, correctness,
currency, completeness and relevance.(128;129)
The NHS CRS was seen as a way to achieving legible, accurate, comprehensive records
(e.g. through using structured forms with mandatory fields). This was linked to other
perceived benefits, such as improved accessibility, storage and searchability of data.
The mix of different computerised and paper systems used in the Trusts with its complex
infrastructure of multiple suppliers, interfaces and several copies of the same data, was
deemed as exacerbating data quality problems (for example in Sites D and E).
However, our research has revealed a far more complex picture in terms of the effects of
using the NHS CRS on data quality. Many interviewees believed that data quality would be
improved in the future; however their opinions on its quality at present (at the time of
interviews) were mixed.
Electronic forms, although often cumbersome to complete, were generally thought of as
more legible and comprehensive than the paper forms. In Sites B, H and Q implementation
team members tended to feel that data quality was improved by the system, particularly due
to mandatory fields in the electronic forms. Some participants also felt that the ability to trace
who entered data or authorised the treatment was a benefit.
However, the following problems with data quality were identified by some of our
interviewees:
• Incomplete data
o Incomplete and free-text rather than coded data for clinical use
o Insufficient data for mandatory reporting and legal requirements
• Unreliable (not accurate or consistent) data
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• Data not useful for practice (not relevant or timely)
• Ambiguity and the temporal nature of data.
Incomplete data
Incomplete and free-text rather than coded data for clinical purposes
A respondent for the CLICS survey (Site D) complained that “there is so little information on
the computerised system, for individual patients that the paper notes have to be referred to
for relevant information, before treatment can continue”. (CLICS survey, anonymous
respondent, Site D).
Users were not always using the system as intended e.g. they were not finalising forms (Site
H). Assigning codes was at times difficult because appropriate terms could not be found or it
was too early to provide diagnosis. In such cases healthcare professionals would leave fields
blank or enter data in free text section: “So if you try and put in another term it comes up
nothing found and you can spend like 10 minutes trying to just find this term […]. I just type
in when they were diagnosed with it underneath it so people know. […] So you actually don’t
have a diagnosis you just leave it empty or you just put it under free text” (Interview,
Healthcare Professional, Site H).
Some users also felt that they might be providing less detailed notes that they have done so
in a paper record. This was seen by some as a potentially negative development, while
others suggested that a more concise style of writing would encourage others to read the
notes. Generally, our observations revealed that many healthcare professionals found it
difficult to enter data while seeing patients. Also, it seems that in Site H the electronic forms
structured to some extent conversations with patients (and hence information obtained and
data recorded).
Insufficient data for mandatory reporting and legal requirements
In Site D, the version of the NHS CRS software (Millennium) in use at the time of interviews
did not allow for recording sufficient data needed for monetary and legal reports, as well as
for monitoring and performance purposes. The Trust retained their paper system because
“Cerner doesn’t keep enough data for you not to keep a Medical Record Department”
(Interview, IT Manager, Site D). In addition, some users including nurses needed to use a
parallel system, so-called CCMDA (Critical Care Minimum Dataset) with Millennium,
“because CRS does not facilitate us for a lot of the data we are mandatory required to collect
from an IT point of view” (Interview, Healthcare Professional, Site D).
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Unreliable (inaccurate) data
The CLICS survey5 distributed in Site D included the following statement respondents were
asked to agree or disagree with: “The information recorded in the clinical computer systems
is usually complete and accurate”. About half of the respondents disagreed or strongly
disagreed that information was usually complete and accurate. The results are presented in
Table 4.11 below:
Answer
Doctor Nurse Midwife Pharmacist Other Unknown %
Strongly Agree 1 0 0 0 0 1 0 0.8%
Agree 34 12 6 0 0 16 0 26.2%
Undecided 25 2 6 0 0 17 0 19.2%
Disagree 47 9 8 0 3 20 7 36.2%
Strongly
Disagree
17 6 1 0 0 7 3 13.1%
[Not answered] 6 0 2 0 0 3 1 4.6%
TOTAL 130 130
Table 4.11: CLICS survey in Site D
Some negative opinions on data reliability were also voiced:
“I can’t rely on any of the figures [from RiO] that are returned to me at the end of every
month by the information team, because I know they are completely false. I know that they
have been for the last six months. I know that they will be for another three or four months.
The business manager also can’t rely on those figures. That’s a disaster. You can’t say
that’s a success. It mightn’t be a failure, but it’s completely disastrous, you know” (Interview,
IT Manager, Site M).
“The information recorded is often inaccurate because the option you need is not given and
there is no facility to record information that you or others might need in the future. You
cannot move forward until you give the system the information it is asking for in the format it
requires which can lead to frustration and the temptation to just choose any option given in
order to move on. This is why I do not think the info recorded is accurate - it is definitely not
5 These views might not be representative as the survey return rate was poor (130 from about 4000)
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complete as it will not allow complete information to be entered." (CLICS Survey,
anonymous respondent, Site D)
The view that “the quality and the quantity is very variable between practitioners” (Interview,
IT Manager, Site BB) was shared by many interviewees. Nevertheless, the expectation was
there that the quality of data would improve with time. Furthermore, despite some problems,
the ability to access patient data and find out ‘who is doing what’ was cited by a number of
interviewees in different sites as a benefit.
Data not useful for practice (as these were neither meaningful nor timely)
A number of users complained about the inability to extract useful information from the
system. This was due to the way the data was reported (e.g. in big, incomprehensible tables,
providing less sophisticated statistical analysis) and accessed (no real-time access to
reporting facilities).
For example, in Site H users anticipated early access to detailed reports on activity.
However, at Time 1 of the study this has not been achieved: “After a year I have nothing but
that I think is down to the fact that the way the information comes out, there’s daily
downloads of massive spreadsheets. They talk about three tables but actually it’s tables you
could wallpaper a room with and our business information unit hasn’t got the man power or
the expertise to actually decipher that data into something that is meaningful reports for me,
and I only want simple stuff.” (Interview, IT Manager, Site H)
While in Site D the interviewees noted:
“We had customised the system over a significant period of time to make it usable and also
to generate accurate statistics. When we took on Cerner’s maternity module it was in no way
as refined as we had had before. It didn’t give us the data that we needed. It was a much
more basic system” (Interview, IT Manager, Site D).
“It was a new system that all the staff had to learn and it didn’t generate the information and
today it still had the information that we need. So it was a retrograde step” (Interview, IT
Manager, Site D).
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“I think one of the biggest things I find frustrating is the report element. It seems to be in a
warehouse, somewhere. It’s like very little I can see access to be able to go into the system
and pull off something you need” (Interview, Healthcare Professional, Site D).
Ambiguity and temporal nature of data
Users were aware that the data on the system might be used by others at different points in
time. This made them somewhat anxious about what data they were entering, knowing that it
might be used out of context. Some also noted that data had to be correct the first time as
the patient might not be around to answer questions at the time when data is being used.
However, certain conditions are ambiguous, and an understanding of ‘correctness’ varies
depending on a person’s perspective.
Furthermore, data is temporal and its validity changes over time. For example, in Site C,
although patients’ referral forms for radiology included questions about pregnancy these had
to be repeated at the time of the appointment. There has to be a place to record such new
data. More importantly, we would add, such ‘redundant procedures’, double checking and
not over-relying on data are to be encouraged.
Confidentiality and Role-Based Access Control (RBAC )
Access to the NHS CRS software systems was subject to the use of NHS SmartCards
enabled with specific Role-Based Access (RBAC) profiles – a series of attributes associated
with different healthcare roles resulting in different levels of access to the patient record.
RBAC arrangements were based on the Care Record Guarantee (see Appendix 14),
founded on the Data Protection Act, and NHS Code of Confidentiality.(130-132) NHS
SmartCards were not specific to the NHS CRS initiative but – at the time of the evaluation –
they came to constitute a new standard across primary and secondary care. Although
nationally led, individual organisations were responsible for setting up Registration
Authorities to oversee local confidentiality and access arrangements. These local authorities
also oversaw the issuing of SmartCards to individual users.
RBAC principles meant that users could only see those parts of the record relevant to their
responsibilities and/or have limited access to certain functionalities. For example,
administrative staff, in principle, would not be able to see clinical details of a patient. RBAC
enabled organisations to identify and track who has accessed records and when. The
underlying aim of RBAC arrangements was to protect confidentiality and prohibit illegitimate
access to records by those who do not have a “legitimate relationship” with the patient.
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Legitimate relationships were based on the principles of workgroups: all staff belonging to
the same workgroup (based on profession and resulting level of access) should have the
same level of access to the record. Again, these structures had to be set up by local
authorities, which at the time of the evaluation had begun in some ‘early adopter’ sites.
NHS staff only received their SmartCard and passwords to access the NHS CRS systems
on successful completion of training: “Everybody had to do two days and then do the test in
the end and get 85% now that you have to get correct answers in the final exam to be able
to get your SmartCard. Yes, there is an exam at the end of the two days. If you don’t get the
percentage you don’t get your SmartCard. You have to get I think it’s 85%. It’s quite high of
the answers correct. If you don’t get that, you have to do a refresher training on the things
that you fail in the test, which is identified then by the trainers and they can focus on the
things” (Interview, Healthcare Professional, Site M).
There were, however, a range of difficulties arising from a strict allocation of roles and
workgroups determining access to the record. For instance, receptionists needed to be given
the same access to all records as doctors in some occasions:
“I think when initially it came in and people saying, there will be role-based access and so if
you are just a receptionist, telephonist booking appointments, you won’t see any of the
clinical records. It transpires that’s not true, because they need to be able to do one
particular thing, which on RiO means they need to be able to get into a particular screen and
in order to get into that screen they actually need to be able to go through the clinical record
and so, therefore, they have access to everything” (Interview, Healthcare Professional, Site
M).
“I think it’s not so much the code, it’s the way we work. I don’t know what it is admin are
needing to do, but the only way you can do it is through going through a clinical record.
Therefore, you have to have access to the clinical record and if you have access to the
clinical record, even a small part of it, you have access to all of it” (Interview, Healthcare
Professional, Site M).
Individuals also often moved from one workgroup to another and a range of teams worked
together to provide care for one patient, in multilayer and complex team arrangements that
did not necessarily match the initial profile model. More flexibility was required, together with
individually defined access profiles:
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“I think it should be individually, because our admin worker here, an admin worker is just a
title and RiO reads that as somebody who just needs access to the progress note and
uploading documents. Our admin worker needs access to diaries and clinical case notes.
She has to put in notes and everything. I had to write and say, no, it’s different and it needs
to be much more full” (Interview, Healthcare Professional, Site M).
“I think it has to be quite flexible. I think because across different organisations and different
roles do different things. Even within our organisation, just because you are a nurse in one
team, […] you may have a different role from a nurse in another team and it means your
access might need to be slightly different. I think it’s right that it’s flexible in that respect. But
then you just need to be very careful that people understand their responsibilities about
having access to it” (Interview, IT Manager, Site M).
The RBAC system was based on the assumption that the person recorded as accessing the
record actually did, or that she has acted on the record on her own. However, this was not
always the case in hospital settings. First of all, NHS staff may have accessed the
record/entered data on behalf of someone else in their team. Typical was the case of junior
doctors acting on behalf of consultants during ward rounds. But also in outpatient clinics staff
may have worked in pairs, with one person entering the data on behalf of the other:
“Some of the high risk clinics we’ve managed to get a little bit faster but then you’ve got two
people working together so one can drive the machine and one can treat the patient, […],
but then you’ve got the issue of whose card is in the machine and who’s treating the patient
and that’s, you know, I’m sure Caldecott would have something to say about that” (Interview,
Healthcare Professional, Site H).
“Yeah, well sometimes you see in clinic because of lack of space this morning we had one
laptop between the two of us so it’s got my card in so even if she treats it’s still on my card
on there which I don’t know how we get on with that, like legalities. Although we’ve both
been there and we’ve sort of been sharing that patient anyway because we’re definitely
talking over, we’re following the patient between us but it’s not always the person who’s
treating who is actually inputting the notes, again because of time restraints in the clinic”
(Interview, Healthcare Professional, Site M).
Secondly, in ward settings NHS staff used shared computers and they would leave their
SmartCards in the SmartCard reader while their work was in progress, when they needed to
move away from the computer or they were interrupted. In the meantime, their SmartCards
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would be used by someone else on the ward. This practice was especially found in
emergency settings, when leaving the computer logged-on would save time: “you won’t
remember to take your SmartCard out and log out. You go and look and there will be a
SmartCard in every terminal in this department right now. If there is a SmartCard in a
terminal already of course you are going to use it, aren’t you” (Interview, Healthcare
Professional, Site D).
Using SmartCards had effects on the ease of accessing the record. These included users
not being able to log into the NHS CRS system, either because they had the wrong access
rights, or because the system would not recognise the card (Lorenzo in Site Q), or, as in the
following example, because the user locked himself out: “One [AHP] also mentioned that he
was not able to use his SmartCard for a week as he had ‘locked himself out of the system’
by putting in the wrong password three times as he did not realize that the cap lock was on.
In this case he had to revert to using paper notes, which he felt was worrying for the future
when the primary record would be held on Lorenzo as there would be no back up system”
(Researcher Field Notes, Site H).
Mostly, users had to wait for authentication before they were able to access the record.
Initially, this took between 30-40 seconds in some Trusts, but was then reduced to around
five seconds. This was particularly disruptive for individuals who moved around and had to
log-on to different machines. Furthermore in some Trusts there was no session persistence
in relation to NHS SmartCard log-in. Both authentication time and session persistence were
not contractually defined. This meant that once the users had logged on for the first time,
when they subsequently logged on they would not automatically be taken back to where they
were, but they had to start the application from scratch.
Controlling access, maintaining security and confidentiality through RBAC had to be
balanced and made more flexible than initially intended, in the trade-off with efficiency and
the reality of patient care.
RBAC, SmartCards and single-sign-on were not part of the NHS CRS, though they were part
of the infrastructure that would enable a smooth and (relatively) controlled access to the
NHS CRS. Investments in this infrastructure were needed for a ‘successful’ implementation
of the NHS CRS.
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Integrated clinical pathways and automated workflow s
One of the reasons for choosing to design and implement a new system (Lorenzo) was that
the NHS CRS was to bring an IT architecture that would enable ‘business process re-
engineering’ in the NHS: “…a single architected application that doesn’t differentiate
between clinical and administrative processes, what it looks at is the patient journey and
sees what other clinical and administrative events that need to be supported” (Interview,
Developer).
Work processes would be “re-engineered” along “multi-disciplinary and multi-organisational”
clinical pathways, also in order to improve “health policy development” (Confidential NME
document from 2004). Advanced releases of NHS CRS software systems were planned to
provide clinical pathways’ functionalities (see Lorenzo Release 4 and RiO Release 2). The
NHS CRS was to drastically change the concept of EHRs, from applications supporting work
in specific settings (e.g. systems for specific wards or clinics), to applications capable of
supporting workflows across intra-organisational boundaries (e.g. hospital ward to hospital
ward) and between organisations (e.g. secondary and primary care, or health and social
care). If the expression ‘integrated clinical pathway’ (ICP) is used in different contexts with
different meanings,(133) from a technical perspective, in the context of the NHS CRS, it was
used to refer to automated workflows along a patient’s journey of care, that integrate clinical
and administrative work: “There are functions in here, lets say I’m a nurse manager, I want
to see my list of my patients, I want to manage my wards but I also want to see what drugs
they’re on, I have to go back and forth between two applications [PAS and a clinical system]
so there’s some disconnect, we can smooth it out with single sign on and things like that,
there’s a bit of a disconnect. There are processes, Integrated Clinical Pathways, ICPs, they
require a combination of specific clinical things which are called from within an administrative
framework of scheduled events…” (Interview, Developer).
Thus NHS CRS software systems were intended to go beyond the traditional electronic
patient record as a database, to a dynamic combination of data, decision-support,
communication, planning and scheduling tools (Site P). The scheduling, order entry, and
requesting, would be automated as a result of events or interventions. ICP would constitute
a really innovative ‘killer application’: “…an active tool to assist in the delivery of care
incorporating clinical decision support to identify actions, reminders and guidance at the
point of care, across the continuum of care” (NME confidential document).
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At the time of writing, these intended advanced functionalities (both for Lorenzo and RiO)
have not been fully implemented.
“One of the things we did look at […] was the thing called, Map of Medicine, which has quite
a lot of the mental health pathways as well. We were hoping at some point to join that up
with records so that we could have […] if you make a diagnosis or something like that and
you can go into get the process of the steps that are needed in terms of managing and
diagnosing those sort of things. They haven’t done that and I don’t know if it’s going to
happen at some point” (Interview, Healthcare Professional, Site BB).
From both a technical and clinical perspective, ICPs require to be specifically designed for
each diagnosis. An NHS CFH Lorenzo team of clinical background was dedicated to the
design of desired paths and clinical forms for each condition, starting from a relatively
simpler, elective one such as hip replacement (Site C), to eventually more complex
pathways (e.g. stroke). Building the Clinical Data Capture (CDC) forms (in Lorenzo) was only
the first step (a ‘building block’) of a long complex process and clinicians using some of
these forms have not yet seen the working of entire automated pathways supporting their
work.
Nevertheless, some changing in integrated working across settings in the NHS has been
taking place. This will be discussed in the next section.
Intra-organisational dimensions and crossing bounda ries
Because the patient journey crosses boundaries of care, clinical and administrative work
also needs to cross inter- and intra-organisational boundaries across both health and social
care services (Table 4.12). The crossing of boundaries was visible, first, in the form of team-
working, with multidisciplinary teams sharing a patient’s care on site or across sites, and
second, in the form of transfers of care, especially with referrals/discharges or requests for
investigations/reports. This section discusses the crossing of boundaries, with a brief
reference to its technical dimension, and a focus on expectations and work practices and the
changing that was enabled (or hindered) by information ‘being digital’.
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Dimensions Issues and solutions
NHS CRS national architecture Technical dimension of
interoperability Record identifiers
Expectations and visions of
shared records
Care across settings and disciplines
Affordances of ‘being digital’
Team-working and information sharing
Communication systems and real-time transmission
Digitally crossing boundaries
Awareness and control for coordination of work
Information governance Confidentiality
Table 4.12: Crossing inter- and intra- organisation al boundaries
Technical dimension
From a technical perspective, NHS CRS architecture was meant to remove the
interoperability barriers in order to enable sharing of data across boundaries and across
software systems (facilitated by the connection to the Spine and the applications of
standards such as NHS numbers). Also, servers were centrally hosted and the inter-
communication across NHS Trusts servers within a same software system (e.g. all Trusts on
RiO servers) was expected to be possible. Still some technical issues existed that hindered
complete use of systems across boundaries. For instance, Site BB – a mental health Trust –
intended to share RiO with social services but encountered infrastructure problems:
“Something on the social services infrastructure, we can’t currently run RiO across one of
their technical environments and it just doesn’t work and at the moment we haven’t managed
or they haven’t managed to find a solution. We are still working on that.” (Interview,
Healthcare Professional, Site BB).
Expectations for, and visions of, shared records across boundaries
The limited scope of the implementation, in the case of Lorenzo, hindered information
sharing across services, but the implementation was progressing with this vision in mind. For
instance, as an IT manager explained, some healthcare professionals’ patients can often
also be seen in diabetic clinics, and these could benefit from accessing existing records in
Lorenzo: “But if you could roll this out for example to diabetes we know roughly a third of the
patients that the [group of healthcare professionals] see are diabetics…So if we can have for
example a one in three hit of the patients that are on the system, you know, so when they’re
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running a community diabetes service that they begin to, you know, look up the system and
find that their patient record is already on there...” (Interview, IT Manager, Site H).
In line with an NHS CRS vision of making patient information available across settings, some
clinicians expected to be able to access records held by other Trusts, especially if these
Trusts were using the same software system. In the case of RiO, the account from the
interviewee below also suggests that the clinician expected record identifiers to be
consistent and usable across settings6: “The worrying thing, we discovered the other day, a
patient came from *Trust B+, which has RiO. They gave us the RiO number and everything
else. What we recognised was that their RiO number was for a completely different person
on our system. So it’s not nationwide. They gave us the number of their person, I said,
brilliant you’ve got RiO. Typed in the number and I said, this is a woman. The RiO number is
different in every Trust. Was that supposed to happen, I don’t know. When I typed in that
man’s name, I had to say to them, that’s actually a completely different woman in our Trust,
so could you give me his date of birth and so I typed in his date of birth and he was there but
with a different RiO number. This is crazy” (Interview, Healthcare Professional, Site M).
Alternatively, NHS staff lamented that NHS CRS implementation disrupted the previously
possible sharing of information when Trusts that were previously using the same software
applications were now on different systems. For instance in the case of Site D: “…we are
sitting here and [hospital x] are up the road and they don’t want to go with, they didn’t want
to go with Cerner and yet we do clinics at [hospital x] and we do clinics here and so we no
longer have that connectivity that we had previously and that’s just a hospital which was
within spitting distance of us” (Interview, IT Manager, Site D).
In Site M, as a workaround to lack of interoperability, a computer with RiO was installed in a
hospital A&E to enable mental health liaison clinicians to access patient information
recorded in other settings.
“Our A&E Liaison Department will be on shift with the Crisis Team member, because it’s not
a Mental Health building, it’s a *Hospital W+ building, general hospital building. We don’t
have network access within that building for our members of staff to be able to access the
RiO information to see if that patient is presented previously within mental health. There is a
6 It is unclear how and why this mix of identifiers occurred; there is a clear potential safety concern in
the use of the same range of record numbers for different settings all using the same systems, if this
is occurring.
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risk there […] and all Trusts are identifying that risk and placing machines co-working with
general hospitals to make sure that we have accessibility to the RiO system there…”
(Interview, IT Manager, Site M).
Clinicians in community and acute settings expressed the wish that the NHS CRS would
enable them to access information from GPs (e.g. in Sites B, C and BB), for instance
accessing GP medication records for accurate medicine reconciliation.
“There is a lot of benefit of patients’ records being electronic because that means that the
GPs can access it and they can put their information on and we can have that information
when we access the notes here. But again, it falls down to sufficient terminals for people to
put that information on.” (Interview, Healthcare Professional, Site C).
A possible solution for information sharing with GPs was seen in the NHS CRS software
integrating with the Summary Care Record (SCR). Although interfacing was to some extent
possible, full integration was not possible at the time of writing:
“…what we’d really, really like to see is summary care record. If the summary care record
was in there we actually wouldn’t even need the GP referral because you could ask the
patient what’s the matter with [them] and everything else would be on there, and there’s a
little bit of arguing and stalling going on about that at the moment. But if you had summary
care record it would really give Lorenzo some value” (Interview, Healthcare Professional,
Site H).
Digitally crossing boundaries
Thanks to the positive affordances of ‘being digital’, having information available in NHS
CRS software systems supported and facilitated: sharing information within teams (e.g.
doctors with nurses); distributing information across teams (e.g. community and acute);
facilitating access to real-time data (synchronously or asynchronously). In the case of RiO,
through the connection to the electronic record, team membership was made more evident:
“The one thing that I’ve really noticed is team-work now. A lot of the teams you would go to
[…] quite often a consultant sits elsewhere from the team. You talk to a consultant and if
they say are you in this team and you say, no, no, I’m not in that team, I work with my
secretary over here and it was very much like that. They didn’t even themselves understand
they were actually part of that team. Because of the structure of RiO now […] people are
actually coming to training and helping each other, which I think is vital, actually. It’s just nice
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to see […]. How long have social services been integrated, you wouldn’t know they were
integrated. RiO has actually brought them together. I know they feel now the full relation with
their infrastructure” (Interview, Healthcare Professional, Site BB).
Also workflow components of the NHS CRS software systems made information transfer
potentially immediate, by enabling real-time transfers of referrals, discharges, requests for,
and reports of, investigations. Information transfer was also expected to be more effective
because information was legible and potentially more complete. Box 4.3 provides some
examples of these practices, continuities and changes. The change was especially
appreciated in mental health community care, as a clinician explained: “I would think that
actually your computerised system is even more important for mental health service than
acute hospital, because of the very nature of how we work. If you are in an acute hospital
your wards are there and your staff is all there and you have a set of notes that you can take
out. The sense is that we are scattered about and we are based in one place and we see our
patients in another place and we see patients at home and patients in A&E department
somewhere. One patient can be accessing five or six different sites in the course of a couple
of weeks. The one thing is you go in and look at it and you know somebody tells you
somebody has been in A&E and you don’t have to ring the A&E and you don’t have to ask
the doctor and you can look at it immediately and see what’s happened. I think that’s the big
advantage.” (Interview, Healthcare Professional, Site BB).
However these positive affordances were often counterbalanced by user interface and
interaction issues, and related data quality problems. For instance, in Site D, Millennium
functionality for requesting tests did not provide a comprehensive list of available tests:
“Some pathology tests aren't listed on CRS as well as some radiology test” (Interview,
Healthcare Professional, Site D).
Furthermore, information available on computers also suffered from being only visible if and
when the computer was accessed. Rarely, it alerted of its presence. Furthermore, electronic
messages often lacked feedback mechanisms, leaving users unaware whether the message
had been received. Thus traditional communication systems were still relied on.
“Q: if someone has been in A&E and you do know about it.
Participant 1: Not always, no.
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Participant 2: They would often let us know and they certainly would know. They don’t have
a system [in RiO] where they are automatically alerted.” (Interview, Healthcare
Professionals, Site BB)
The absence of systems for alerts and/or feedback mechanisms raised issues for
coordination of workflow and patients’ flows. This was the case, for instance, in Trust B,
where clerks lost control of the ward, where patients were, which ones had been discharged,
which patients were booked for a scan:
“…they still haven’t resolved the operational thing for the wards knowing what’s going on so
if somebody needs a scan and maybe that’s discussed outside of the ward round and then
they send the request down on the system the nurse coordinating the care still doesn’t know
that that’s been done unless you go in… that’s the biggest issue for me … oh it’s huge. If
you’re coordinating a ward, and it has resulted in us not preparing patients for that scan …”
(Interview, Healthcare Professional, Site B).
“…I think that’s a kind of real requirement [for Lorenzo] ... Because what we do is we give
views against patients, so they’ve got to go into a patient, come out and go into the next one
come out to find out what’s going on...” (Interview, IT Manager, Site B).
Similarly in Site H, administrative staff had not been alerted by Lorenzo if referral letters had
been issued by GPs, so they had to keep checking the system to see if the letter had come
through. In Trust C, a workaround with paper was devised as a ‘flag’ to alert the ward that
patients had gone to and returned from X-Ray: “…our X-Ray is out of the department. And
so we needed still to give the patient’s paper in order for them to know when they arrived in
X-Ray that the people in X-Ray knew and for us to know when they come back from X-
Ray…. We need a better system flagging when patients have been and come back from X-
Ray ...When they come back we need something in clinic to say that they’ve returned so that
we can bring them back into clinic, so [paper] is a flag for the professionals as well”
(Interview, Healthcare Professional, Site C).
Users of Millennium encountered similar issues. For instance, in Site D a user commented:
“…the lists should be easier to see what each patient is having done rather than having to
click on each patient which is lengthy and time wasting” (Interview, Healthcare Professional,
Site D).
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Millennium has a system of pushing reports into clinicians’ inboxes, thereby alerting them of
their availability. However, in Site D (and also Site R) this functionality could not be relied on:
“Results are variably sent to clinicians (i.e. I can't rely on all results coming to my inbox) and
it is not unusual for senior clinicians to receive results on children that they have had no
involvement with which is of concern” (Interview, Healthcare Professional, Site D).
“Not all XR /MRI reports come back to the person requesting them, especially where the
initial referral was to another person in the team. This means there is a constant worry than
something might be missed or get lost. It is impossible to keep double checking everything
you do …” (Interview, Healthcare Professional, Site D). In Sites D and E, work is going on to
create “favourites” boxes for clinicians to help address such problems.
Information governance
Clinicians working in mental health in Site M valued the ability to access patient information
across settings, though others were concerned about the confidentiality of their mental
health patients data (for instance, for patients in a forensic mental health setting, Box 4.3)
(Site G).
Referrals “[RiO] sometimes makes things for our patients easier in terms of waiting. … if I want
to refer for example to a day centre, I would write a referral form and then send in CPA
and then send in risk assessment and then wait for them to kind of meet them up.
Actually, they can now go and I can say, here is the referral form and they can go on
RiO and have a look at the CPA…” (Interview, Healthcare Professional, Site M).
Discharges “… we used to do that on our wards on a piece of paper called a discharge summary
… sending that electronic discharge form electronically to primary care that's a
massive step forward for the NHS because it's now almost immediate, it's legible, it's
complete, there's all sorts of information you can put it in there .... But in effect what
we're doing is we've electronised the piece of paper and sent that electronic paper to
primary care" (Interview, IT Manager Site B).
"[…] we currently produce something called a flimsy document which is carbonized,
three sheets of paper, it's recognized as being not fit for purpose, clinically unsafe,
can't communicate it and all this sort of stuff, so it should be an easy win. But because
it's taking us 20 minutes to produce an electronic version of it and it takes 5 minutes to
produce something that doesn't work we're being measured against the 5 minutes, so
straight away it's seen as a disbenefit because people don't recognize, they don't want
to recognize that fact that the source document is not fit for purpose" (Interview, IT
Manager, Site B).
"When we go-live with the new discharge summaries …what that will enable us to do is
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make sure the doctors record diagnosis procedures and investigations on Cerner, …
and then the discharge summary will pull those fields to create the discharge summary
automatically. Also that will, hopefully, we will link it to our [xxx] site so the local GPs
can pick it up, so there's lots of things but we've been working on this a year to get a
new discharge summary" (Interview, IT Manager, Site E).
Requests “…a doctor fills in a request card and depending on the scenario, …[it] gets delivered
into our department .... That request card is then entered onto our system. From then
onwards, it’s kind of processed through the system. Whereas an electronic request is
actually somebody in Lorenzo fills in a request that drops automatically into our
system. Somebody looks for that electronic request and then processes it through. …
The process is the same, in a sense, it’s just that one is a paper source and one is an
electronic source” (Interview, Healthcare Professional, Site C).
Information
sharing
“For example, CPAs, we don’t have to kind of duplicate a lot of things. … say, risk
assessments and risk incidents…. Information that we were kind of having to email to
the ward or kind of distribute within the Trust, we can now say, it’s all on RiO and just
have a look” (Interview, Healthcare Professional, Site M).
“When doctors do ward rounds, what we used to have is that if somebody from our
team couldn’t attend […] somebody else would go. They might have written a note in
the patient paper file saying, attend the ward round and see this person and just do a
couple of lines of you know for follow up on her return and I want to know what’s been
discussed and then I would have to chase the doctor up or chase the ward up. The
ward might have not put in the community slant of things on their ward notes. And then
information would have gone amiss or they would have been delayed. Now I can just
log in and have a look at the patient notes and I can see what the ward has entered”
(Interview, Healthcare Professional, Site M).
“…is the pathway of the joint replacement patients … a lot of the pre assessment clinic
information obviously comes with the patient to the ward. But, unfortunately, the wards
went live [with Lorenzo] before the pre assessment did. In fact, the pre assessment are
still not live with Lorenzo. That means that information from pre assessment still came
in paper form, so the ward staff then had to upload a lot of that information
electronically, whereas, if that part of the pathway had of been live first that information
would have already been on. …” (Interview, Healthcare Professional, Site C).
“Yeah it is because now we know that definitely everybody has access so things like,
so last week we had a really urgent […] surgery on the Wednesday and I could actually
book her in to have it on the Thursday knowing safely that her assessment was all
there and I didn’t have to rush off a set of notes and everything else it was all done.
And that’s only minor benefits for us but everyday where we use it more and more now
we’re paper free we just think of more things” (Interview, Healthcare Professional, Site
H).
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Team-
working
“One of the nurses in our Memory Service called me in the week and I said, oh, this is
what we need to do in relation to the medication. I was thinking it would be great when
I’m on RiO, because what I’ll do is, I’ll just quickly type that in you know, at the time,
rather than sort of thinking, well, she’s got the notes so hopefully she’ll make the entry
confirming what I’ve said. I’m relying on her to do that, whereas I’ll be able to kind of
check much more” (Interview, Healthcare Professional, Site M).
“… we actually had still running 19 Legacy systems. So not only did we have very little
information that we actually could share within the same teams, we couldn’t share
anything across teams. And certainly, we had this horrible mix of teams treating
individuals and they didn’t even know that each other were seeing the same person .
We had a desperate need for something let’s just say something like RiO as in a single
electronic record, which the practising clinicians and the support staff could use as
one” (Interview, Healthcare Professional, Site BB).
“But certainly on a positive side it’s all the kind of stuff that is the inter agency stuff you
will be making affairs from other teams or you are receiving affairs from other teams
(Inaudible 00.21.45) it makes life so much easier” (Interview, Healthcare Professional,
Site BB).
Box 4.3: Information sharing and information transf er across settings
The experience of change
Experience of change is a fundamentally complex concept in that it is constituted by
temporal, relational, cognitive, technical and natural aspects of change. In many cases
narrating experiences simultaneously involves evaluation of these experiences i.e. positive
versus negative experience or bad versus good experience. Findings suggest that
participants (i.e. implementation team members, healthcare professionals, and
administrative staff) had mixed and varied experiences of the implementation and adoption
of the NHS CRS software that cannot be outlined in their totality in a single section. For this
reason, this section outlines the main factors and conditions that shaped individuals’
experiences, also summarised in Table 4.13, and, in doing so, describes some of the most
representative experiences. It is important to note that patients’ experiences are not outlined
in this section because out of the 33 interviews that we conducted only two patients were
aware of the NHS CRS and even those did not know how to differentiate it from other
computerisation initiatives in the NHS. Patients did however express their experiences of
NHS computerisation, expectations of the NHS CRS and projections in the future.
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Sources of experience Aspects of experience
Time Projection Remembrance Present dis(benefits)
Self and Others Identity Peers Engagement
Knowledge IT use IT literacy Learning
Technology Maturity Implementation
strategy
Monitoring
Change Nature Resistance Working-out change
Table 4.13: Sources (and their aspects) that shaped participants' experiences of the
implementation and adoption of the NHS CRS
Time: projected benefits and implementations, past experiences of IT & NHS
initiatives and present (dis)benefits
Participants’ experiences of the processes of change that the NHS CRS initiated were
influenced by the way in which they projected its benefits in the future. Some participants for
instance foresaw the future link between the NHS CRS and the SCR and anticipated great
benefits from accessing more comprehensive, and especially clinical, GP data.
Respondents’ experiences were also shaped by the way in which they projected NHS CRS
implementation in the future, which they considered as being larger in scope, i.e. Trust wide
and inclusive of more functionalities: “I think there’s nine phases, we’re in the first one,
people probably think oh my goodness I can’t hack another eight of them, it’s going to be too
hard…So if you think, like if you say to staff that you’ve only got one little bit of it and they’re
battling with that one little bit and they’ve got eight more phases and it’s going to go on for
the next, I don’t know four or five years (laughs), oh it will never be done by 2012, then that’s
demotivating people, you just think ohh.” (Interview, Healthcare Professional, Site Q).
Not only individuals’ projections for the future but also their memories of the past shaped
their experiences of the NHS CRS implementation and adoption.
Specifically, respondents’ experiences were shaped by the use of computer systems in the
past. In Site H for instance users’ attitudes towards Lorenzo were influenced by their
negative experiences of the use of iPM, also developed by iSOFT: “…if I’m really brutally
honest, you know, if you talk about CSC or iPM to a user I’m not sure they’ll talk in a very
positive manner about them. It’s a fact, I’m afraid…” (Interview, IT Manager, Site H).
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Lack of such past negative experiences with a supplier had a beneficial effect on shaping
positive attitudes towards Lorenzo implementation in Site Q: “I think one of the good points is
that they, unlike perhaps other Trusts they didn’t actually have a clinical system before hand
so therefore, you know, they’re not sort of comparing it to a clinical system that they had
before, so I think they like the look and the feel of it” (Interview, IT Manager, Site H).
In addition, past experiences of users’ involvement in NHS initiatives shaped their attitudes
towards the NHS CRS: “And that really, and I’ve worked in the health service 29 years and
I’ve seen a lot of things like that happen particularly in the last, …we’re probably talking the
last 10 years or so, so many initiatives, as I say nothing to do with computers, so many
different initiatives that come in and they get us all involved and, you know, we all spend
loads of time on training and having these things implemented and then a year later they
shelve it all. And as I say this is just, to me this is just another one of those so when I hear
the negatives that it’s not going to carry on, it just really annoys me…” (Interview, Healthcare
Professional, Site H).
Participants’ experiences were also framed by current benefits and disbenefits of NHS CRS
systems delivered. Healthcare professionals from Site H saw clear benefits from the system,
such as completeness and availability of information, to such an extent that they ‘hate to use
paper now’ and would not like to go back to using paper notes: “From when we first started
to now there’s massive differences and I can’t imagine as [Name1 0.48] was saying going
back to paper notes.’” (Interview, Healthcare Professional, Site H).
In contrast to this, respondents from Site H would rather argue that the system far from
being beneficial provides “just more work”: “…if I said what’s the benefits of using Lorenzo at
this present time I would probably say none, there’s no benefit to me at all. It takes longer to
do than paper notes, you can’t see the last treatment that you wanted to, you still can’t co-
ordinate your care between departments because we’re not at that stage, so at the moment
no there’s no benefits” (Interview, Healthcare Professional, Site H).
Professional identity, peer relations and engagemen t with the NHS CRS
Participants’ experiences were also influenced by social relationships. Specifically, our
findings suggest that experiences were shaped by the way in which the NHS CRS aligned
with participants’ sense of their professional identity, by their peers and by the level of their
engagement in the NHS CRS implementation.
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Many times participants’ experience of the NHS CRS was dependent upon the way in which
the system complied with their sense of professional identity. For instance, some participants
from Site B reported that constant use of computers was ‘not really what they signed up for’
and interviewees from Site H argued that Lorenzo would attribute to their profession
technically and take away clinical responsibilities: “…especially when it started for the first
few months it was very much, we felt like IT people, we felt admin people instead of actual
clinicians because we were spending more time with this system than we were actually with
the patient” (Interview, Healthcare Professional, Site H). Other participants from Site H saw
the use of the system as being a part of their job and thus were happy to continue using it
despite its limitations: “To be honest I don’t have any bad or good feelings about it to me it’s
just something that I’ve been asked to do so I do it” (Interview, Healthcare Professional, Site
H).
Participants’ experiences were also influenced by the feedback they would receive from
colleagues. For instance, the second wave of healthcare professionals that used Lorenzo
had negative views about it because they heard from their colleagues that it was initially very
difficult to use: “Well I’d seen it in use but to be honest I kept a distance from it because I
thought I wasn’t going to be involved at any time and I had quite a negative opinion of it so I
just thought I’m not going to get involved in it, its caused all these problems” (Interview,
Healthcare Professional, Site H).
Also, experiences were shaped through knowledge sharing with other implementer sites.
Participants from Site D reported that site visits made them more conscious about the
difficulties of the implementation process and more optimistic seeing that the product can be
made to work. Specifically, as a consultant said, site visits “changed a lot of opinion here, a
lot of the consultants who were a little bit negative suddenly realised, right, this does work.
We can use it” (Interview, Healthcare Professional, Site D). Also, a representative of an SHA
from the Southern cluster argued that the experiences of one Trust were “…obviously
influenced and I suppose it’s kind of confirmed what people felt” (Interview, SHA). The
impact of this sharing was so powerful and effective that some interviewees from Site R
reported that they were not allowed to share their experiences with others in order to
minimize their influence on future implementer sites: “Once we had gone live with us then I
thought, it’s part of my job now as a part of the NHS community to make sure other hospitals
don’t suffer. I wasn’t allowed to tell other hospitals how bad it was” (Interview, Healthcare
Professional, Site R).
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Users’ experiences were also shaped by the level of their inclusion and involvement in the
implementation of NHS CRS systems. As a manager in Site C said “… you can explain to
them all the benefits, look, these are the reasons we’re doing it and they’re good reasons.
The people here can see that and they’re good people, they all want patient care to be better
and they all want things to be good” (Interview, IT Manager, Site C). Indeed, deep
involvement made some healthcare professionals from Site H describe the system as their
“baby”.
By contrast, when users thought that the NHS CRS was being implemented in a top-down,
and thus exclusionary way, then it conditioned low morale and negative feelings: “I think
people have used it because they’ve had to and it’s been, you know, it’s directive from the
Trust, and it’s quite clear that that’s what we have to do … But certainly at the time of it
coming it really hit team morale, it really, people really struggled with it” (Interview,
Healthcare Professional, Site Q).
IT use, literacy and learning
Positive and negative experiences of the NHS CRS could be influenced by the users’
familiarity with IT use and literacy and ability to learn new skills. Participants who described
themselves as “techies” were sometimes, but not always, more positive towards the NHS
CRS in comparison to those who were “not computer minded” at all. A role was played by
the participant’s age. A researcher noted down in her field notes that: “Both users and
implementation team members felt that users from the older generation often struggled more
than others with learning how to use Lorenzo and computers in general. Problems
mentioned in this context included issues with typing and issues in motivation to use
computers as it was difficult to learn for some” (Researcher Field Notes, Site Q).
Also the need to update and expand IT skills, as technology was becoming a part of their
everyday job, shaped healthcare professionals’ experiences of the NHS CRS: “I think a lot of
them don’t feel confident and they are frightened. It’s fear. It were never part — it would have
never been part of their role, ever…they fear the fact that it’s IT and they don’t want to cross
over into that boundary. It’s a bit fearful for them’” (Interview, IT Manager, Site C). Although
evident across all software systems, this was particularly true for many users of the NME
cluster who had to constantly re-learn new releases of Lorenzo that became sequentially
available.
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Technology: Maturity, implementation and monitoring
Interviewees’ experiences of the implementation of the NHS CRS were influenced by the
maturity of the product. Depending on their perceptions about the product users had different
experiences to report. For instance, one healthcare professional from Site H said about
Lorenzo: “I don’t do computers at all but I find it really simple, easy to use and I love it, no
problems at all….. I find that all the information is all to hand which is, I find that makes my
life easier” (Interview, Healthcare Professional, Site H) whereas another healthcare
professional said for the same product: “…I’ve been involved with it for over three years now.
I’m hugely disappointed, because it’s not delivered… It makes everything much much
slower. And they hate it. Nurses hate it” (Interview, Healthcare Professional, Site C). Also, a
participant from Site R commented on Millennium they implemented: “IT is terrible…It has
cost us millions of pounds. It’s brought out hospital nearly to its knees. It’s destroyed staff
morale” (Interview, Healthcare Professional, Site R). There was also a general concern
about data safety which made many participants mistrust NHS CRS systems: “…it’s not
safe, because it’s a computer system. A lot of people think that computers are not 100%
safe and don’t trust them… The minute you take familiarity away that they start, it’s not going
to work” (Interview, IT Manager, Site C).
Apart from the product it was the site’s present and future implementation strategy that
influenced interviewees’ experience. For Lorenzo users the gradual implementation process
created insecurity due to the fact that they were preparing a lot for a product that did not
arrive in the way in which it was originally planned: “…the difficulty has been managing
expectations. I think the end users feel they have been lulled into a false sense of security so
when we get this system, it was going to be doing all this and that we were going to get it
soon, the implication was that it would be fairly easy to implement and it hasn’t been”
(Interview, IT Manager, Site C).
Also, participants from Site R reported that their, largely negative, experiences of the
implementation of Millennium were shaped by their limited choice over the product and the
implementation process. As a consultant argued people’s morale and confidence were
affected by the fact that the system was perceived as being “…imposed rather than we had
willingly signed up to this” (Interview, Healthcare Professional, Site R).
Also uncertainty about the future strategic direction of Trust, of the whole Programme and of
future resources and support – especially as concerned with key members of
implementation team who worked on contracts – were important aspects that influenced
interviewees’ overall experience of the NHS CRS to the point where they started questioning
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the value of continuing working on the project: “I think people get a bit, is it worth it? Is it
worth me continuing? Should I put the effort in? I don’t know where I’m going to be this time”
(Interview, IT Manager, Site C).
Interviewees’ experiences were not only shaped by the implementation of the NHS CRS but
also by its consequences. Specifically, interviewees were concerned about the monitoring
aspects of NHS CRS systems, which conditioned a pressurised environment to work within
and loss of confidence in the technology: “I think what it is I don’t think, I don’t think people
have confidence in what they’re doing so they’re worried. Anything you put on Lorenzo stays
on Lorenzo whether you strike it out it stays on, so if you make a mistake it’s going to be
there and it’s going to be recognised as you so I think there is a lot of pressure on people…”
(Interview, Administrative staff, Site Q).
Change: nature and resistance
Interviewees’ experiences were also shaped by their perceptions about the nature of
change. Thus, they would often legitimise negative experiences by linking them to a
necessarily painful process that precedes change: “…but it’s a journey to getting to that
endpoint and I don’t think you can get there without some pain and without learning some
lessons…” (Interview, IT Manager, Site Q).
Further, one of the most common justifications for participants’ negative experiences was the
perception that clinicians resist change. This was almost presented as a taken for granted
part of clinicians’ nature: “The users don’t like change, they never do. …They don’t like the
struggle with change” (Interview, IT Manager, Site C).
Rather than accepting clinicians’ natural proclivity to resistance our findings suggest that
resistance came from participants’ anxieties about working-out change, perceived
shortcomings of software functionalities and dealing with its implications.
Some respondents thought that change would take a lot of their time, energy and intellectual
capacity, rendering the change that the NHS CRS initiates threatening: “I think it’s the
application of a computer system is threatening. It’s a change and it take if you like
intellectual capital, it takes time and it takes energy and you might see your contribution to it
is actually giving, but not getting anything back” (Interview, Healthcare Professional, Site C).
Others were afraid that they wouldn’t be able to learn new skills and thus make proper use of
the system. This made “people …frightened they may lose their job” (Interview, IT Manager,
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Site C). Some others were afraid of failing to meet expectations and to deal with a possible
failure: “…there’s an awful lot of people who are just worried about having their name
attached to it if it does fail and I think that’s causing some of the problems around getting
people to sign up…” (Interview, IT Manager, Site H).
Also, participants were often concerned about the way in which the NHS CRS influenced or
would influence the way in which they worked, their productivity and their routines: “It was
quite a shock to not being able to do the things that they are used to doing on Word, for
example, very easily to do CPS or risk assessments” (Interview, Healthcare Professional,
Site M).
4.4.6 Organisational learning
This section describes the processes put in place by the Trusts to support learning and
learning that had taken place related to: (1) managing and implementing large-scale IT-led
organisational change projects; and (2) utilising IT to support organisational and healthcare
goals (e.g. how to realise benefits envisaged from the NHS CRS). These two areas require
learning of different skills and acquiring different capabilities, e.g. from an ability to use the
software to perform simple tasks to developing IT-supported practices that help to achieve
organisational goals.
The assumptions here are: first that organisational learning takes place at different levels
(individual, group and organisation) and involves feedback between those.(134) Thus, this
section discusses learning by and between individuals, groups and the Trusts. Secondly,
organisational learning consists of different social and psychological processes, including
sensemaking, sharing ideas and developing common meanings and institutionalising (i.e.
embedding into organisation or routinising).(135;136) Learning can be supported by formal
processes, e.g. training, or be an outcome of doing things (learning-by-doing). Indeed,
learning need not be conscious or intentional.
Processes in place to support learning
Processes put in place to support learning within individual Trusts and between Trusts
included ongoing support and training on the NHS CRS software systems and related work
processes (described in section 4.4.5), local interim evaluations, lessons learned documents
on the implementation process, as well as forums and meetings organised by the SHAs and
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NHS CFH. Informal ways of learning mainly included on-hand support from group members
belonging to the same Trust and cultivating relationships with members of other Trusts.
Evaluations
Local interim evaluations were in some cases conducted as a part of the deployment
verification process and benefits realisation assessment. Also, our team members provided
informal, formative feedback to each site on their staff’s attitudes, lessons from the
implementation process and the systems’ implications for the way healthcare is delivered
and the implementation is managed in their Site. However, gaining understanding of the
implications of the NHS CRS software systems was constrained by a number of factors,
including early stages of the implementation and adoption, changing software, lack of
agreement on baseline measures, assessment measures and targets, as well as complex
environment characterised by many other change initiatives taking place simultaneously7.
Lessons learned documents
Generally, lessons learned documents from other Trusts were seen as not very useful.
Some felt that due to the fast moving nature of product development, these documents might
be out of date relatively quickly and not be relevant for a wider implementation. Others
considered the documents as too long and overcomplicated.
“Much of what you would read in these lessons learned would either be so complicated that
you couldn’t really learn from it. If they told you the route that they’ve gone from London to
Brighton via Edinburgh, you would get bored. Whereas really all the information that you
needed was, it’s impossible to go from London to Brighton for what you needed to know. It
wasn’t sort of condensed in that way” (Interview, IT Manager, Site R).
More significantly, perhaps, knowledge cannot be simply imparted (in a package of lessons
learned documents), but needs to be internalised and ideally gained through experience.
Interviewees felt that certain lessons had to be learned by doing and as this was the first
ever national implementation of the software it was difficult to plan for everything in advance,
particularly that each Trust was different.
“I think some basic principles are absolutely transferable. But they do come down to details
that are not transferable, because they are very specific to an individual organisation. […]
7 Difficulties with evaluating outcomes of information systems implementations intertwined with
complex organisational change processes are well documented in the academic literature.
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each Trust has to have its own systems and its own difficulty with simple things like the ratio
of secretaries to staff, the presence of ward clerks, you have them 24 hours a day on a ward
or only 9-5. It’s a question of which staff are going to be using the system and how”
(Interview, Healthcare Professional, Site R).
Staff feeling submersed in the “here and now” could make it difficult to take someone else’s
lessons on board.
“We had all of the lessons learned documents from all of the previous go-live sites, apart
from [place] and [place], but all of the other ones didn’t help us at all…. It’s a difficult thing to
understand why it didn’t. I think we were so submerged in, have we got that sorted out? […]
We shouldn’t have the problem that they are having should we, because we’ve got a
workaround. You ended up actually with the same problem, but you just had a very
convoluted workaround that took huge amounts of resources to make it happen” (Interview,
Healthcare Professional, Site R).
“The fact that we had carefully documented all of the lessons that we’d learned and there is
a huge document out there somewhere saying all of that. A subsequent go-live site in
London learned absolutely zero” (Interview, IT Manager, Site R).
This interviewee even suggested that “there is a cliff just there and people have to walk to
the edge” (Interview, IT Manager, Site R).
Forums and meetings
Various forums and groups for representatives from Trusts, LSPs and NHS CFH to meet
were set up. They were mostly seen as valuable but not always as responding to the needs
of people ‘on the ground’. For example, In NME, ‘early adopters’, NHS CFH and the LSP
(CSC) met at an Early Adopter Forum monthly to facilitate learning across sites, e.g. to
discuss issues ‘early adopters’ encountered such as configuration, training and requirement
analysis. The meetings were organised at a project management level with limited
participation of the people who were hands-on the actual roll-out and use of the software
(LR1). As a result, they tended to focus on the management rather than the implementation
of Lorenzo.
The Southern cluster care plan group, which included clinicians, met monthly to discuss
issues related to RiO. These were seen as useful. However, according to an interviewee,
information was not shared between clusters and more could have been learned from the
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Trusts in London which implemented RiO earlier. Nevertheless, s/he later stated that “we are
starting to work together and we’ll start to share experiences […] but at the moment it’s only
just starting to happen” (Interview, IT Manager, Site BB).
The role of NHS CFH in facilitating contact was perceived as ambiguous. Some appreciated
its coordinating efforts, whilst others saw it as constraining direct communication between
‘early adopters’. Some felt that sharing experiences was not encouraged and that this might
almost be done intentionally in order to prevent individual Trusts “ganging up” and “pulling in
the same direction”.
However, other interviewees described the NPfIT and its associates as effective in their
exercise of the implementation of the NHS CRS, because a platform was created to “learn
from the places that got it wrong and the places that got it right and to sort of use that as a
vehicle for securing trouble free deployment through the rest of the Programme” (Interview,
IT Manager, Site D). They thought there was enough learning now to be able to roll-out the
NHS CRS, so “to step back from it now I think would be wrong” (Interview, IT Manager, Site
D).
Informal ways of learning
Our research indicates that the Trusts perceived informal ways of learning as more
beneficial. Members of different Trusts developed relationships with each other in order to
“share experiences”, ask specific questions regarding the implementation or management of
the system, and invite members of other Trusts who experienced the implementation to visit
or work alongside them. The discussion between the Trusts was not limited to project
management issues but also included learning about different work practices, e.g. through
informal comparisons of procedures or forms used.
“Possibly one of the most valuable things that one could do for a site that was going live is to
take somebody like me and then plonk them in [another future Millennium site] wherever it is
and say: You can’t do it that way. You do it this way” (Interview, IT Manager, Site R).
However, for those on the ground, contact with other Trusts was viewed as difficult
(acknowledging time and geographical distance constraints). Furthermore, sharing lessons
with others was also seen as potentially distracting from the main task of implementing a
system as this was often time-consuming with different stakeholders from different
organisations often asking the same questions. Also, some interviewees suggested that not
everyone wanted to “tell the truth”.
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In summary, our research suggests that sharing of lessons learned and communicating
between ‘early adopters’ was viewed as very important but somewhat difficult to achieve and
also as – perhaps as is inevitably true – something that could have been done better.
Learning that had taken place
Learning about managing and implementing large-scale IT-led organisational change
projects
The staff developed knowledge of managing implementations of IT systems (e.g. in terms of
allocation of resources, organising training, cultivating relationships and involvement) as well
as gaining more technical skills (e.g. about systems integration).
It also appears that the Trusts and perhaps the NHS more generally, had accumulated some
knowledge about IT-led programmes of change, and understandings (but not necessarily
shared understanding) of what such change means to the NHS and how IT might be utilised
to facilitate changing. One of the Trust managers suggested that as a result of many years’
attempts “there are a lot now of experienced people that understand what this type of
change means to the NHS and how to help them to make that happen that I think you
wouldn’t want to lose that” (Interview, IT Manager, Site D). However, as people leave this
knowledge might leave with them.
Our research also suggests that NPfIT had ‘pushed IT to the fore’ and that the Trusts are
more aware of the potential of IT to meet evolving national as well as local NHS needs. This,
in somewhat extreme terms, was expressed by one of the interviewees:
“RiO pushes IT to the front of that and just as important as clinical practices. And so,
therefore, the Trust needs to have an ongoing budget to be able to maintain their IT
equipment and also look at advanced technologies, i.e. handwriting recognition that can go
directly into RiO” (Interview, IT Manager, Site M).
“So the Trust needs to be aware … that no longer is IT the naughty little boy that sits in the
corner. It is now in the centre of the room and has to be addressed and has to be listened to,
because if IT department says, this cannot be done then, the Trust has to realise that it has
a direct impact on their clinical care, etc,” (Interview, IT Manager, Site M).
Lessons learned about how to manage such future initiatives included the importance of
sharing information between Trusts, considering benefits to the Trust before committing to
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implement, analysing and perhaps standardising workflows and work practices before
computerising them, and allocating adequate resources. Although it was acknowledged that
sharing data across professional teams and organisations required some level of
standardisation there was no shared understanding on how standardisation should be
achieved.
“I’ve definitely come to the conclusion that [‘brutal standardisation’] is just wrong.
Localisation is very important to individual hospitals. The trick I think in an IT system is to
make the underlying structure equivalent so that you can then compare like with like with
different hospitals and you can produce regional and national data with ease. To make the
bit at the front end look different” (Interview, IT Manager, Site R).
Learning to utilise IT to support organisational and healthcare goals
At the time of the research it was too early for the new practices to be fully institutionalised
and new innovative ways of working, taking full advantage of functionalities offered by the
NHS CRS systems to emerge. New working practices arise not only through planned actions
(e.g. an introduction of a computerised referral system) but also through day-to-day use of
the system, and people finding out how the system works and how it can be made to work
for them.(87) Our research indicates that the healthcare professionals learned new IT skills,
become more familiar with computers in general and specifically with the NHS CRS
software, and developed their understanding of what such system might mean for their work
at present and in the future.
One interviewee expressed a concern that the need to make savings in the new economic
situation would mean that the support required in terms of training and access to experts
would not be provided and as a result “the huge change that you were asking about in terms
of working practices will not happen. People will do what they’ve always done” (Interview, IT
Manager, Site BB).
In summary, our research indicates that the Trusts developed knowledge relevant to
managing other large-scale IT-led implementations and change programs. The staff’s e-
literacy, including an understanding how IT might effect their work practices and healthcare
in general increased. However, it is only through using the systems that opportunities for
learning new things and new (and hopefully better) ways of doing things with IT will arise.
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4.5 Conclusions
The major insight that any interested observer should draw from the experience of the NPfIT,
and in particular the progress with deploying software systems to support the NHS CRS in
secondary care setting reported in this chapter, is that implementing clinical operational
systems of any richness is not a straightforward activity.
It is hard, takes time, and needs to be approached carefully and as more than a one-way
implementation effort led by (or delegated to) technical experts and project managers,
particularly if they are removed from the context of system use.
Rather, we must understand that among important requirements for the deployment of such
systems, such as the need for strong commitment from the organisation’s leaders, perhaps
the most important principle is:
It is the clinical and administrative staff who have to work day-by-day to make such
systems work. Their commitment to do this work needs to endure for as long as a
system is in use.
The reader may find this a rather trivial and obvious assertion. We would argue in reply that
much of the evidence collected in WPs 1, 2 and 3 suggest that this significant principle has
at the very least been often lost sight of. More importantly, by firmly restating it and following
the implications, we can develop new and stronger ways of thinking about how the potential
of information technology and information systems can be realised in healthcare.
In this conclusion section we briefly follow through some of the implications that derive from
our research findings and this guiding principle.
4.5.1 Vision and purpose
Our research shows that the NHS CRS embedded various visions that are expressed in
different accounts of its intended purpose. We identify three broad and distinct components
of this vision, balanced in different ways among our various respondents. These we have
labelled as data-centric, business-centric and policy-centric views (Table 4.3).
It is quite legitimate and indeed necessary that different people, and people in different roles,
should hold different views about the NHS CRS or any EHR project. But a consequence that
follows is that the overall deployment approach needs to give space for each perspective to
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be accommodated and developed over time. In particular a simple data-centric view that
over-emphasises data and information at the expense of workflow, clinical innovation,
business change, management and policy ambitions, will be unable in the longer-term to
engage the system’s users. Embodying these various perspectives and allowing them to be
reflected within an existing healthcare organisation as it introduces new systems makes
certain demands, not least on the technology itself.
First and foremost the technology has to be ‘fit for purpose’, passing a basic test of utility and
reliability. Our respondents often reported a deep sense of the immaturity of the software
solutions on offer. Beyond this basic test, not always passed, we have seen the enduring
debate over the constraints and governance structures that support software configuration
and the negotiation of the limits of customisation of chosen software systems to meet Trust’s
expressed needs. We have found that administrative, technical and clinical users at the
Trust level are often quite aware of the main themes in the complex debate as to the mix of
standardisation and localisation that is appropriate, and report negatively on the lack of
attention to supporting positive change in local work practices. Often, it seems, they would
like to be able to take a stronger role in working out the inevitable compromises. But the
complex supply chains and convoluted communication processes between Trusts, LSPs,
software developers and NHS CFH, together with the commercial nature of LSPs’ and
software developers’ relations, often led to a perceived premature establishment of fixed
outcomes (what is to be achieved) and a lack of attention to productive processes (how
different positive things could be achieved). Thus participants raised normative concerns as
to whether NHS CRS software should be customised, reflecting on the risk of it becoming
dissociated from its understood central purpose or of having its code fragmented such that
ongoing support and upgrades would become very hard to undertake. Others insisted on the
common information needs of clinicians but also on their tendency to protect their
professionalism by encouraging unnecessary or dysfunctional differentiation.
Just as we should draw lessons from the way in which technology has been drawn into NHS
CRS implementations so too we should consider the role of healthcare organisations. Our
studies have shown a variety of approaches that were taken to preparing for implementation
and a number of factors that seemed to have shaped them (both enabling and impeding
them). For example, some departments or areas may be more computerised than others,
multiple projects and initiatives often ran in parallel with the NHS CRS and could have
rendered its implementation of secondary importance. Over the time span of this study,
changing NHS policies added further uncertainties and further delays to the process – for
example working to achieve Foundation Trust status, and then the new powers it offered.
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More concerning, the fundamental disjunction between a Trust as the ‘client’ or problem
owner, and their lack of budgetary control or direct communication with the service supplier
(e.g. software company) could lead to a sense of detachment or inevitability.
4.5.2 Implementation vs. adoption
This chapter started with a model that differentiated implementation from adoption. In the
studies reported here we see this distinction between implementation and adoption was
blurred, with often limited or partial account taken of the latter. Especially in the case of
Lorenzo, built while in use, the fundamental implication of the approach taken – that users
should feel able to contribute and be major actors in shaping the systems – was not always
achieved. Rather, the cycle between user and developer was too often extended and
fragmented and the ongoing process at times clashed with the structured approach
embedded in software contracts and processes of requirement specification.
More generally, and taking the perspective of adoption, we see that the introduction of NHS
CRS software influenced changes in the work practices of a variety of stakeholders in clinical
and non-clinical roles. As systems were implemented people within the Trusts studied
reported varied experiences and emotions, often reflecting temporal perspectives such as
the way in which they projected the NHS CRS into the future and its anticipated benefits,
their past experiences of the implementation of computer systems, and the immediate
benefits and disbenefits they saw during implementation for themselves or for the patients
they directly worked with.
A sense of achievement (or not) was also often reflected in the way in which individual
respondents and their peers identified themselves as clinical professionals and the degree to
which this was reflected in the system they came to use. Consistent with the overall
sociotechnical model introduced at the start of this chapter, we find that this link to a
professional identity, be it as a nurse, doctor, ward clerk or healthcare assistant, is probably
more important and significant than levels of IT literacy per se or willingness to expand IT
skills.
We deliberately include in the list of ‘professionals’ ward clerks and healthcare assistants.
The NHS CRS is often portrayed as a set of clinical systems with primarily clinical users, but
the users of the software studied here were often AHP and administrative staff. Yet their
interests seemed to have been too often ignored in the wider plans and their concerns not
captured as implementations went forward. In a number of cases NHS CRS software
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systems offered functionality for these types of user that were either ‘not ready’, required
duplication of work in parallel systems, revealed data migration problems or slow responding
infrastructure. Usability problems were often encountered. These problems could become
critical, not least in reducing commitment or enthusiasm of the systems users, and directly
reflect the consequence of a narrow understanding of the clinical role of these systems. The
result was, inevitably, locally developed workarounds, especially to overcome constraints in
coordination of work or when the systems did not fit the needs found in the context of use. At
times such workarounds lead on to data quality issues.
We also see that using the NHS CRS in day-to-day tasks tended to be perceived as
requiring more time than previously and as a consequence the NHS CRS was seen by some
as reducing the time for direct patient care. We have also seen clinicians required to enter
data in NHS CRS systems, a redistribution of data entry work often up the hierarchy – e.g.
from admin staff to clinicians, from nurses to doctors, from junior doctors to consultants, etc.
If data entry in NHS CRS systems is envisaged as happening ‘at the point of care’, this
should not be surprising, indeed it might be welcomed. However, concurrent data entry while
with the patient was most often done on paper, the data entry referred to was done
retrospectively, raising in turns concerns for efficiency and safety.
Nevertheless and despite such concerns, enhanced management of data and its availability
was usually perceived as a benefit as when information was legible, available in ‘real-time’,
more easily searchable and retrievable, accessible ‘any time’ and ‘anywhere’, by multiple
concurrent users. Electronic transmission of messages (referrals, requests, reports, etc)
were reported as making some workflows faster in their totality, though more or less time-
consuming in some stages, and for some of the staff involved. To make the most of these
data sharing and transactional benefits, a critical mass of users and data needed to be
achieved, and this required time and a continuation of faith in the system while volumes built
up, data quality issues were addressed and new practices were established and absorbed
into the work team.
4.5.3 Crossing boundaries
The ambitions of the NHS CRS from the outset included the ability to move clinical data
between healthcare settings. At the Trust level this suggests the digitalisation of integrated
multi-disciplinary clinical pathways, seen by some as a means to ‘business process re-
engineer’ the NHS. However, no NHS CRS software implementations studied here included
such functionalities and most sites studied were some way from considering such issues in
earnest or at a Trust level. Indeed, we saw that the process of designing digital support for
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integrated multi-disciplinary clinical pathways, or even establishing the tools needed to do
this, revealed the deep ambiguity of the term pathway and the complex organisational and
medical ecology that they exist within. Our finding, consistent with the principle established
at the start of this section, is that such computerisation of clinical pathways is a complex
process that requires intense engagement among multiple stakeholders, and is not
principally achieved by means of some specific functionality designed into software systems.
On the broader theme, our research has, however, shown that digitalisation can facilitate
sharing information across teams or services within a Trust, by making information available
concurrently and in real-time.
The next step, crossing organisational boundaries, is needed for ‘joined-up’ patient-centred
care. One of the NHS CRS systems implemented (RiO) was more successful than others in
this regard and revealed how computerisation can support team working across
geographical and institutional boundaries.
4.5.4 What has been learned: What might we do next?
The guiding principle established in the introduction to this section has one final important
implication. As healthcare organisations engage with the NHS CRS or other EHR or eHealth
technologies, and as they work-to-make-it-work, they can and should learn. Our data
suggest that, in all the sites we have studied, significant organisational learning has indeed
taken place – even in those with the worst experiences. People, through their experiences
good and bad, are able to reflect and adapt their understanding and to achieve a quite subtle
understanding of the complexities of making these systems deliver to their potential, and few
report a diminished commitment to the idea, even if they have firm opinions on what they
would like to do differently if given a chance. But often the response to us as researchers
when we invited such a conversation was of relief and gratitude that at last somebody was
asking them. At the individual level, as well as within professional groupings and even
among Trusts, the potential to respect, enhance and support such learning is clear. By
taking such a route the real long-term benefit of the NHS CRS in the past decade may
indeed be found, emerging from the foundations laid by the NPfIT.
The following section summarises lessons learned from the research described in this
chapter.
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4.5.5 Key lessons for implementing EHRs and other s imilar health information
systems
The lessons presented in this section are based on findings from our qualitative research
into the NHS CRS. However, they are relevant not only to the NHS CRS but also to other
similar systems. They are divided into lessons for policy; for design of such systems and for
their implementation locally and presented in Boxes 4.4, 4.5 and 4.6 below.
Complex systems such as EHRs will always need (at least some) configuration at the level
of Trust / settings and it is unrealistic to expect otherwise. Hence, we suggest that:
- Contracts with software suppliers should be open to an incremental and iterative definition
of requirements.
- NHS Trusts implementation strategies should cater for an iterative and incremental roll-out
of functionalities, and an IT system ‘growing’ in time.
- Adequate resources need to be allocated for those processes.
- Configuration requires direct channels of communication between the implementer
hospitals and software suppliers. Intermediaries cause bottlenecks in the communication
and slow down collaboration.
- Configuration requires a clear and transparent contractual relation between the involved
parties. The contract needs to identify the sites as the clients of EHR systems, to outline
clear specifications provided primarily by the implementer sites, to specify what parts of the
software are amenable to change and to set feasible timelines that appreciate the complexity
and difficulties associated with implementation and configuration processes.
- There has to be national agreement over the degree of software configuration and
standardisation permitted. Presupposition for this is that decision makers are aware of the
design of the solutions that are to be implemented and of the clinical and business
processes these solutions will support. This would hopefully lead to software that meets both
national and local purposes.
Expectations regarding the outcomes should not be set at unrealistic levels.
- Our research indicates that paperless work practices are difficult to achieve: e.g. they
require complete computerisation of all processes for all stakeholders, availability of time
and resources for concurrent data entry, intuitive and fast software interfaces available on a
variety of hardware, including easy to handle mobile devices. These may be necessary, but
not sufficient conditions for aspects of care to become paperless.
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- Procurement decisions should not be based primarily on unrealistic assumptions of
achieving cost-savings or even returns on investment, but rather on introducing clinical as
well as administrative functionality early so that these systems are used.
National EHR implementations start off with a core vision, which through time gets
interpreted, translated and modified to a number of visions in line with implementers’
understandings, healthcare organisations’ needs and local strategies and evolving political
and economic context. Different visions should be accommodated and supported in as long
as they are aligned with national and local strategies.
Information systems take time to embed in organisations. Their utilisation and different
implications (e.g. for practice, efficiency, user satisfaction and health outcomes) vary with
time. Hence, evaluations should be done at different points in time, not only immediately
after the implementation. Longitudinal evaluation is most desired if we are looking to
understand processes of change.
Box 4.4: Key lessons for policy
There is a need for a shared understanding among all stakeholders of the purpose and
content of the system to be designed.
Successful design of future technologies relies on understanding of the context of use. For
example, we found that community settings tend to lend themselves better to a model of
shared care (or at least shared information) underlying the vision of shared EHRs.
The physical environment (e.g. space) and the nature and time of the clinical encounter (e.g.
pre-booked versus ad hoc) will affect to what extent a computer system is used, and in
particular if data can be entered at the time of a clinical encounter. This has to be reflected in
the design and implementation of such software and in the preparation of the environment in
which it will be used.
Providing relevant functionalities is a necessary (but not sufficient) condition for the
successful adoption.
- The systems need to be ‘fit for purpose’. Configuration can only be successful in as long as
the product provides functionality that is useful for the implementer healthcare organisations.
- The systems should satisfy both the needs related to the care of a specific patient and the
needs of users managing patients’ flows and groups of patients (e.g. wards). Changes in
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patient status (e.g. admitted/discharged, or test requested/completed) should be highly
visible at both levels.
- Reporting functionalities are key features of electronic patient records that enable evidence
based management of NHS services at local level. Such systems should be built on indexes,
databases and interfaces that enable clinicians to have direct access to their data in real
time. Centralised data-warehouses are not equivalent alternatives to reporting functionalities
directly accessible by clinicians.
EHR systems and their use need to comply with the ways in which users identify themselves
as professionals.
Delivering visible benefits is very important.
- The systems should deliver noticeable benefits to the immediate users not just to the NHS
as a whole, i.e. to the health and allied health professionals, managers and administration
staff and ultimately patients.
- The systems should be focused on helping the NHS organisations to deliver performance
standards (e.g. referral within X amount of time).
An appropriate design process is needed.
- The principles of User Centred Design (UCD) should inspire the design process.8
- The adoption of agile methods for software development might make it easier to locally
configure the systems and to do so within realistic timescales.
Box 4.5: Key lessons for design
The implications of new systems (such as EHRs) will vary from site to site, as any new
system needs to co-exist with and affect established work practices, norms, power and
control mechanisms amongst other things.
Decision to implement EHRs or any such system should be a conscientious choice of each
site.
8 UCD is an engineering model that seeks to understand the users of a technology, their needs and
context of use, to inform the design of a new technology. It does so by engaging with users
throughout the design/implementation process, and by iteratively evaluating prototypes or interface
designs before final implementation, within a cycle of requirements elicitation-design-evaluation-
revision of requirements.
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Sites need to be given the freedom to set up their implementation strategies depending on
their previous experiences of IT implementation and use, local priorities, legacy systems etc.
Apart from being (financially) incentivised healthcare organisations need to become ready to
accommodate the new systems and their prospective changes.
There is a need for a long-term strategy and for a continuous support from the top
management and (influential) clinicians throughout often long process of implementation/
configuration and post-implementation.
Managers need to shape and maintain users’ expectations of EHRs pre-during and post
implementation. They need to provide a clear reason and a long-term strategy that will
maintain users’ enthusiasm and engagement.
Organisational learning within and between the NHS organisations needs to be given high
priority and full hearted support. Informal channels and relationships appear to be more
effective for learning than formal channels such as ‘lessons learned documents’ which, even
if shared, are seldom read and even less likely to be reflected in practice.
Allocating adequate resources (e.g. for support activities, extra clinical staff to cover for time
lost for training and learning the system while in use, etc) is essential. Extra resources will be
needed for some time after the system implementation, (although the first few weeks might
be the most resource intensive) and some will be required indefinitely (e.g. for IT support). It
is easy to underestimate the effort and resources required.
Before the system is designed or implemented an overview of current work practices and
work flows should be done to consider how they can be improved, e.g. standardised and
normalised, and potential problems that might be brought about by computerisation need to
be identified.
Hands on, one-to-one and preferably peer-based support in the first weeks of and after the
implementation is very important (even more than formal training).
Training strategy needs to be as flexible as possible, i.e. opportunistic, changing with the
circumstance and tailored to diverse users’ needs and their roles. Training is an on-going
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process, and plans for training new staff (in particular rotating junior doctors) need to be in
place.
Ideally training should be delivered no earlier than a week before the system’s go-live date
but as it is not realistic with a large number of users, special attention needs to be paid to
providing ongoing support and ‘learn and play’ realistic environment where users can use
the system without changing live data.
Box 4.6: Key lessons for local implementation and a doption strategies
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Chapter 5: Assessing and understanding the costs of implementing
and adopting the National Health Service Care Recor ds Service
5.1 Introduction
Electronic health record (EHR) systems hold the promise of improved safety, higher quality,
and greater efficiency of healthcare.(137) Despite this promise, few hospitals have as yet
implemented and adopted such systems due in part to their inhibitory cost and the
uncertainty that surrounds their return on investment. As the core component of England’s
National Programme for IT (NPfIT), EHR systems were procured centrally rather than locally
at an estimated cost of £12.7 billion.(10) The complexity of the implementation of this facet
of the National Programme posed an immense evaluative challenge. This was because
there was only very limited previous research specifically concerned with the evaluation of
implementations of the National Health Service Care Records Service (NHS CRS),(138) and
comparative quantitative studies evaluating different forms of EHR are virtually unknown.(19)
A systematic review of the literature found that studies’ description of the implementation
process and EHR systems was limited, thus making it very difficult to ascertain whether
some capabilities were absent or simply not reported.(19) In addition, empirically measured
cost data were found to be limited and inconclusive.
Previous US and UK evaluations of Picture Archiving and Communications Systems (PACS)
and EHR systems have used some form of ‘before and after’ comparison of costs.(139-141)
Other studies have used a modified Delphi technique to obtain an expert group consensus
on estimated costs, which were unavailable from the published literature or from primary
data.(142) This consensus-based work has however not captured all relevant cost
categories – for example, unforeseen costs associated with productivity loss (during
unscheduled system or network outages) had not been adequately considered. Walker et al.
have suggested that a phased approach to EHR implementation may reduce costs, but this
assessment was based on only limited evidence.(143) In addition, the size and complexity of
the organisation may mean greater implementation costs associated with system integration.
Methods of cost-effectiveness analysis exist for technologies prior to investment or
implementation, such as the so-called “headroom method”, an approach to establishing an
upper bound to implementation costs that can preserve cost-effectiveness.(144) These
methods can be employed to some extent in investigating new technology implementations
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in the face of front-loaded uncertainty. However, this approach cannot easily be used for
multiple-production technologies in an environment such as a hospital Trust.(145-147)
Hospitals are characterised as multi-output producers: they use all inputs more or less
simultaneously to produce all outputs, and the process is seldom tractable. That is to say, a
given input cannot be tracked through a production process to a given output. This is
required across inputs and outputs in the producer – in the case the hospital Trust – in order
to quantify: (i) benefits; (ii) induced/opportunity costs; and (iii) process changes due to the
new technology, which are necessary to quantify the impact on the costs of other factors,
such as hospital Trust characteristics. Therefore, production and costs are not homothetic
(or related) with respect to something as far-reaching as a new, comprehensive IT system.
This has been found elsewhere; Himmelstein et al. for example, analysed linked data from
4,000 hospitals in the US, but found no savings overall in administrative costs.(148)
However, this is too narrow an area in which to define relevant benefits, including cost-
savings, a point reinforced by Arlotto and Oakes' criticism of focussing on return on
investment analyses on operational and tactical benefits, as relevant costs (whether called
disbenefits, induced costs or opportunity costs) will be missed.(149) Studies focussing upon
setting (e.g. a physician practice outpatient setting) were similarly restricted in their
findings.(150)
A recent systematic review found limited literature on commercial, multifunctional health
information technology (IT) systems.(151) Moreover, they stated that little information
existed on contextual factors and process changes associated with large-scale
implementation of health IT systems. This is not surprising given the immense difficulties in
isolating tractable, quantifiable changes or even grouped inputs, process or outputs of
production with regards to technology and technology changes mentioned above.
This is an important consideration for our evaluation, given that we sought to categorise
implementation costs, because these have direct implications for costs associated with
workflow and process – specifically productivity losses, or so-called induced costs.(142)
Training costs that involve staff back-fill, for example, are very difficult to track without an
auditing tool in place. Similarly, productivity losses due to process cannot be tracked through
the process change itself. For example, a paper order form was routinely held to be faster to
more complete than the NHS CRS equivalent; however comparative completion times will
vary by: individual; NHS CRS software system; clinical functionality involved; level of
training; and by level of staff performing the task. A simple before-and-after survey of task-
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completion time is possible, but only with specific measurement and auditing tools available
prior to implementation. None of the Trusts studied had chosen to monitor the task-
completion time and no post hoc evaluation can capture such data, for the reasons
discussed.
This work-package (WP) examined the cost of implementing the NHR CRS in hospital
Trusts. There is no standard evaluative framework in place to assess the costs of EHR
implementation and adoption, and implementation of an EHR on this scale is
unprecedented.(152) Moreover, it was difficult to extrapolate findings from existing studies to
different health systems such as the NHS: we therefore needed to obtain the necessary
hospital Trust costs and construct the cost framework de novo using appropriate techniques.
5.2 Aims and objectives
5.2.1 Original aim and objectives
The original aim of this WP was to assess the costs of NHS CRS implementation from the
perspective of the NHS Trust-level.
We sought to:
• Assess exceptional introduction per-provider costs
• Assess annual (recurring) per-provider costs
• Develop evaluation frameworks to assess the impact of the NHS CRS on costs
• Validate cost categories with local providers and with NHS Connecting for Health
(NHS CFH)
• Make recommendations about a core dataset for NHS CRS evaluation post-
implementation.
However, the national implementation and roll-out of the NHS CRS underwent substantial
contemporaneous change during our study (as discussed in Chapter 1). Most importantly for
this WP, the difficulties in finding areas of enquiry that could be replicated across the
different systems (or different functionalities in different releases of the same system), along
with a reluctance to provide documents containing cost information at a Trust level, meant
that a revision of both the aim and objectives of this WP was necessary.
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5.2.2 Revised aim and objectives
The revised aims of this WP were slightly expanded i.e. to assess and understand the costs
of NHS CRS implementation at Trust-level. However, our objectives to satisfy this aim
changed.
We sought to:
• Identify the exceptional (start-up) and annual (recurring) per-provider costs;
• Explore the perspectives of NHS CRS implementation staff, including clinicians'
views, on the different start-up and recurring costs, and on the factors which impact
on the amount of resource spent by hospital Trusts;
• Categorise and describe implementation costs (the cost framework), validate the cost
categories contained within it with local providers and with NHS CFH;
• Develop a Minimum Data Set (MDS) to evaluate NHS CRS implementation costs.
5.3 Methods
5.3.1 Sampling and recruitment
Recruitment and selection of hospital Trusts
We collected economic data from Trusts that were part of our 12 case studies. These
included hospital Trusts across London; the North, Midlands and East (NME); and Southern
England implementing centrally procured NHS CRS systems. Purposive sampling was
guided by the research aims of this WP to include hospital Trusts implementing different
types of NHS CRS system (i.e. Lorenzo, Millennium and RiO).
Recruitment and selection of participants at hospit al level
Details of relevant hospital staff (e.g. Director of IT, Finance Director) were obtained from
site leads and approached directly by the researchers to arrange a suitable time and place
for interview. All participants within the hospital Trusts were selected if they met the sample
inclusion criteria stated above. In the later stages of interviewing, this was also influenced by
the attainment of thematic saturation. The researchers judged that thematic saturation had
occurred when the themes suggested by interviewees began to repeat themselves and
subsequent participants' interviews yielded no new themes.
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Recruitment and selection of participants at Strate gic Health Authority (SHA) and NHS
CFH level
At NHS CFH level, individuals were approached opportunistically at national conferences
and meetings. Contacts within NHS CFH provided details of staff that were involved in the
implementation of the NHS CRS at SHA level. At Trust, SHA and NHS CRS levels,
participants were asked if they could also provide the details of any other individuals within
their organisations who may be able to provide relevant cost information.
5.3.2 Data sources
Interview data was obtained from a total of 36 different participants. Some participants were
interviewed more than once, as indicated below; other interviews were conducted in pairs,
as requested by the participants.
Implementation team members included mixture of change managers, project managers,
programme managers, and benefit leads. Users interviewed consisted of a mixture of ward
managers, consultants, and nurses. Field notes were also collected.
A summary of participant details, including participant code, is given in Table 5.1.
Participant Code Times interviewed
Site B.ITman.CQ.20.04.09.NOTT01F
Site B.ITman.SC.CQ.25.06.09.NOTT18F
2
Site B.ITteam.CQ.20.04.09.NOTT02F 1
Site B.Fin.Dir.CQ.20.04.09.NOTT03F 1
Site B.ITteam.CQ.21.04.09.NOTT04F 1
Site B.ITteam.CQ.21.04.09.NOTT05F 1
Site B.HCP.CQ.21.04.09.NOTT06F 1
Site B.HCP.SC.15.05.09.NOTT10T 1
Site B.ITteam.SC.22.05.09.NOTT12T 1
Site B.ITteam.SC.29.05.09.NOTT13T 1
Site B.ITTeam.SC.24.06.09.NOTT16T 1
Site B.HCP.SC.CQ.24.06.09.NOTT17F 1
Site B.ITteam.SC.CQ.25.06.09.NOTT19F 1
Site C.ITteam.SC.CQ.26.06.09.NOTT20F 1
Site P.ITteam.SC.CQ.23.07.09.NOTT21T 1
Site H.NLOP.SC.CQ.19.08.09.NOTT22F 1
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Site H.NLOP.SC.08.10.09.NOTT26F 1
Site H.HCP.SC.08.10.09.NOTT27F 1
Site H.ITteam.SC.08.10.09.NOTT28F 1
Site H.FinDir.SC.CQ.16.10.09.NOTT29F 1
Site H.FinDir.SC.CQ.16.10.09.NOTT30F 1
Site H.ITteam.SC.CQ.16.10.09.NOTT31F 1
Site E.ITman.SC.CQ.26.10.09.NOTT32F 1
Site H.ITman.SC.18.12.09.NOTT34F 1
Site D.FinDir.AT.CQ.16.03.10.NOTT36F 1
Site Q.ITman.SC.19.03.10.NOTT37F 1
Site Q.ITteam.SC.19.08.10.NOTT42F 1
Site J.FinDir.SC.AT.04.10.10.NOTT43F 1
Site H.ITman.SC.01.11.10.NOTT44F 1
Round 2: To verify the cost categories contained wi thin the MDS
with Trust participants
CfH.SC.CQ.14.01.10.NOTT35T 1
Site B.ITman.SC.26.11.10.NOTT45F
Site B.ITman.SC.12.01.11.NOTT52F
2
Site B.FinDir.SC.26.11.10.NOTT46F
Site B.FinDir.SC.12.01.11.NOTT53F
2
Site E.ITman.SC.CQ.16.12.10.NOTT47F 2
Site E.ITteam.SC.CQ.16.12.10.NOTT48F 1
Site C.ITman.SC.21.12.10.NOTT49F 2
Site C.FinDir.SC.21.12.10.NOTT50F 1
CfH.SC.10.01.11.NOTT51F 1
Table 5.1: Summary of participants' details includi ng participant code and
organisation
We also obtained the following range of local cost documents from Trusts:
• Business cases, which contained projected costs
• Project Initiation Documents (PIDs), which also contained projected costs
• Actual expenditure data, which varied in time period collected, e.g. one year post ‘go-
live’.
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Filename Site Software Description
NHS CRS Expenditure Report (2007) Site E Millennium
NHS CRS financial
report
Appendix _NHS CRS Financial Report Site E Millennium
NHS CRS financial
report
Appendix _Training Plan Site E Millennium NHS CRS training
NHS CRS High Risks & Issues Site E Millennium
NHS CRS risk
assessment
RiO Full Business Case Site M RiO
NHS CRS Business
Case
PID Site M RiO NHS CRS PID
NLOP Resourcing Site H Lorenzo
NHS CRS financial
report
PID Site C Lorenzo NHS CRS PID
Local cost reporting tool Site C Lorenzo NHS CRS Expenditure
NHS CFH NHS IM&T Investment Survey
2008.pdf NHS CFH
NHS CRS financial
report
Copy of Local NHS CRS business case
VFM tool.xls NHS CFH
NHS CRS business
case
Resource Budget Site B Lorenzo
NHS CRS financial
report
EPR Next Stage Business Case Board Site B Lorenzo
NHS CRS Business
Case
Product Initiation Document Site B Lorenzo NHS CRS PID
WES.doc
Computer
Sciences
Corporation
(CSC) Lorenzo Technical Specification
NAO_2008.pdf2 National
165
Audit Office
Reporting Update Site D Millennium
NHS CRS financial
report
NHS Cerner Implementation Site D Millennium
NHS CRS financial
report
IT Director's Report Site D Millennium
NHS CRS technical
report
CRS Finances Site D Millennium
NHS CRS financial
report
Planning Overview Site D Millennium NHS CRS planning
Table 5.2: Detailed documents assessed
5.3.3 Data generation and handling
We undertook a mixed-methods approach to establishing the cost framework. This involved
first using microeconomic production models to identify domains of inputs that could be
affected by a broad-reaching technological change within a hospital setting (e.g. EHR).
Qualitative research methods (semi-structured interviews, documents and field-notes) were
then employed to identify the costs involved in implementation and explore the factors which
impact on the amount of resource spent at trust level. Financial, planning and other
resource-use documents obtained from hospital Trusts were also assessed in order to
specify inputs within these domains and estimate their values. Finally, a second round of
purposive interviews was conducted to formally verify our cost framework and MDS with
Directors of IT, Finance Directors, and NHS CFH staff.
Semi-structured interviews
Interviews took place between February 2009 and January 2011, and lasted from 20
minutes to two-and-a-quarter hours. Prior to the interview, each participant was informed of
its purpose and reassured that all information supplied would be treated in the strictest
confidence. Any personal details and information, which could lead to a participant being
identified, were removed at the data transcription stage and a code applied. The interview
schedule (see Appendix 15) consisted of open-ended questions on topics underpinning the
WP’s aims and objectives. Every attempt was made to improve the clarity of questions for
participants over the course of the interviewing period, with some being reformulated as
understandings emerged. All participants were asked towards the end of the interview if
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there was anything else they would like to add to increase understanding of the issues
discussed, and also whether they were willing or able to provide any documents relating to
implementation costs or activity.
Documentary evidence
Documents containing cost information (e.g. business cases, PIDs, financial reports, current
and previous expenditure files) were requested from each Trust as mentioned above, and
relevant data (e.g. cost categories and figures) were extracted from them. Available data and
evidence generated by other WPs was also assessed, so as to ensure that all costs were
included appropriately. All documents reviewed and assessed are listed in Table 5.2 above.
Through this process a framework was developed, which characterised likely, representative
implementation costs.
Validating the cost framework
The process of validation involved presenting the developing cost framework to Directors of
IT and Finance Directors at hospital Trusts implementing different NHS CRS systems, and to
members of the Project Advisory Board, Independent Project Steering Committee, NHS CFH
Benefits Realisation Team and other key NHS CFH members of staff. Each of the cost
categories were discussed in turn and any suggested changes they would make to the
overall layout, cost categories and sub-categories sought. This process enabled us to reflect
on whether such a framework contained all the necessary cost categories for Trusts
deploying different systems, different sets of functionality, and commencing from different
starting-points (thus aiding generalisability). This also ensured that the cost framework could
function as a MDS (see Appendix 16) to be used by other Trusts implementing NHS CRS
and to guide future evaluations.
Sensitivities of getting the information
We faced a number of challenges collecting cost data from hospital Trusts. First, hospital
staff appeared to be reluctant to be interviewed when approached. There may have been
many reasons for this, including the substantial costs associated with implementing an EHR
system and the highly publicised losses reported by some Trusts.(153) Second, for those
who agreed to be interviewed, issues were raised surrounding ‘the identification of the
interviewee’ or ‘Trust’, and ‘the comparing of one Trust to another’. This problem may have
been exaggerated by the apparent lack of communication between Trusts. Third, documents
containing actual expenditure data of the hospital Trust were rarely provided. These
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documents were viewed by hospital staff as confidential in nature and containing sensitive
information, which was unpublished and not available to the public.
Validity, reliability and generalisability
A number of strategies have been incorporated into WP4’s methodology to help strengthen
validity and reliability. These include data triangulation and peer de-briefing. The
triangulation of data sources was a guiding principle of this WP’s design. To ensure the
credibility and trustworthiness of study findings, different sources of data both from within
and between hospitals, SHA and NHS CFH were obtained. This process not only provided
considerable insight into the various costs associated with NHS CRS implementation, but it
also added `weight' to findings by revealing similar factors that impacted on costs.
Supplementary data, in the form of detailed field notes and documentary evidence (e.g.
business cases, project initiation documentation and interim financial reporting), also offered
the ability to triangulate methodologically.
During the various stages of data collection and analysis, the researchers took every
opportunity to discuss their interpretations and findings with colleagues to increase the
Trustworthiness of the study. As suggested by Russell and Kelly,(154) this “team based"
approach allows multiple, diverse perspectives to be considered at each stage in the
research. Although it is encouraged that this process of “peer de-briefing" should engage
colleagues outside the research study,(155) experts on our Project Advisory Board were
consulted in an attempt to reduce the possibility of researcher bias and encourage
reflexivity.(156)
5.3.4 Data analysis
Phase 1: Qualitative data analysis
Data analysis aimed to identify major cost categories associated with the implementation of
an EHR system and the factors that impact on the amount of resource spent by hospital
Trusts. This systematic and rigorous process was initiated with data collection. Throughout
the interviewing process the researchers thought about the data being gathered, refined
questions, pursued ideas and investigated further cost categories in greater depth. A
thematic framework was developed by identifying the recurring themes and concepts. A
workable list of main- and sub-themes was applied systematically to the whole dataset with
the aid of the computerised qualitative data analysis software QSR N-Vivo version 8.(157)
These data were then sorted and synthesised by grouping data with similar content. This
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reduction, ordering and collation enabled the researcher to concentrate on each specific
theme in turn, looking across different hospitals and understanding the range of views and
experiences shared by interviewees. The researcher moved backwards and forwards
between the data, using the “constant comparison” technique,(158) and evolving
explanations, until a fit was clearly made. Participants' own explanations for particular
phenomena were investigated and the diversity of their accounts explored. This process
involved interrogating the dataset as a whole to identify linkages between sets of
phenomena and exploring why such linkages occurred. In the quotes presented below,
words in square brackets [ ] and ellipses (...) were added; the former to clarify meaning, the
latter to indicate the removal of unrelated text.
Documents were also analysed to obtain a contextual understanding of the costs relevant to
particular Trusts. Using our cost framework, developed from the initial round of interviews,
our documentary analysis determined whether we had included all relevant cost categories
appropriate to NHS CRS implementation. By conducting this analysis across a number of
Trusts, a more complete understanding of all relevant costs emerged which, in turn,
increased the generalisability of the data set.
Phase 2: Quantitative data analysis
Financial and other resource-use data sourced from documents could not be analysed using
a standard meta-analytical approach (e.g. relying upon transitivity and points in
common).(159) This was due primarily to the incompleteness in data provided at the Trust-
level (e.g. some provided capital but not personnel costs), and the substantial heterogeneity
between Trusts (e.g. at different stages with different functionalities).
Reported amounts of resource use were analysed, giving due regard to costs that were
considered ‘more certain’ and those that were ‘less certain’: the latter were costs that varied
too greatly between Trusts (because they were too dependent upon choices made at the
Trust level during implementation), or because they were opportunity costs that were not
easily captured by accounting procedures (such as the utilisation of existing space, reliance
upon staff goodwill to commit their time, etc.). In terms of economic analysis these are two
different categories of uncertainty; this is addressed later on. The framework used to initiate
this approach was based upon a standard production function, where the domains of the
impact of NHS CRS implementation can be identified: in terms of the levels and productivity
of personnel, capital expenditure and IT/technology (i.e. other IT/informatics systems).(160)
Assuming a hospital Trust attempts to minimise costs, whilst maintaining treatment and
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overall quality, one can expect that a change in IT technology – NHS CRS implementation –
can feasibly affect each of these. At the same time, the impact of the implementation can be
dependent upon the existing levels of personnel, capital and IT; their existing efficiency; and
the scale of the hospital Trust overall. This allowed us to categorise the domains of impact,
with our purposive interviews identifying other site-specific costs as the framework was
developed.
5.4 Results
5.4.1 Phase 1: Qualitative results
The cost framework
A cost framework was developed to identify, categorise and describe the range of
exceptional (introduction) and annual (recurring) per provider costs associated with
implementing an EHR system. The main cost categories in this framework include:
• Infrastructure (refers to key IT architecture required to implement EHR e.g. hardware
and software)
• Personnel (all staff costs related to EHR and implementation of EHR, including
training)
• Estates (costs incurred while installing an appropriate environment for EHR)
• Other materials and costs.
The key costs associated with each element were also considered, and presented in the
framework.
This framework was developed from interviews and documentation, but also designed
according to conventional production models under technological change:(146;160) factors
that affect levels of capital and labour employed during production (hardware and personnel
in particular); factors that affect the efficiency or productivity of both existing and acquired
capital and labour (either level or type: including different types or utilisation of computers,
the integration of specialised management in the process, for example); and factors that
affect the level and productivity of technology itself (such as server and data backup costs,
ongoing oversight of data integrity). The framework also matches those found in other
industries.(161)
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Importantly, our cost function includes technology costs themselves, in the form of
superseded hardware and software, as well as interim hardware and software required. This
is important because we cannot make assumptions about either economies of scale (the
degree to which increasing IT expenditure is beneficial, depending upon the size of the
Trust) in Trusts, or returns to scale of the new technology that the NHS CRS represents (the
degree to which improved IT can increase efficiency, via the NHS CRS). This, in turn, makes
it much more difficult to estimate the effects of the technological change.(162) Importantly,
this also captures the potential for the NHS CRS to deliver early disbenefits before longer-
term benefits.(149)
There are a number of major factors that impact the cost of EHR implementations, including
size and complexity of the project. Different hospital Trusts may choose to implement the
same software e.g. Lorenzo or Millennium using different approaches, and some may also
choose to integrate different software applications (already in existence) with these systems
by following the same procedures. However, all these factors can impact on the cost of NHS
CRS system implementation. We highlight the costs involved and also discuss the factors
that were found to affect the amount of resource spent in each of these categories.
Finally, there are also important distinctions to be made between the costs of implementing
NHS CRS in individual Trusts, in those who have chosen to be ‘early adopters’, and in those
who have also agreed to be ‘early adopters’ and beta-testers of the product. In the current
environment, and in our data, ‘early adopters’ of Lorenzo were partners in development in
ways that ‘early adopters’ of Millennium were not. The costs incurred were not tractable in
this regard, although the extraordinary development costs tended to consist of increased
expenditure on hardware rather than issues relating to personnel or business processes.
Infrastructure
We define “hardware” as the physical units that make up the computer, such as the system
unit, keyboard and monitor. We found that Trusts purchased and deployed a range of
different types of hardware to support EHR implementation, including: standard PCs,
computers on wheels, wall-mounted computers, keyboards, tablet PCs and printers (mobile
and heavy duty). SmartCards were supplied to the Trusts studied free of charge by NHS
CFH. There was also a maintenance cost associated with resolving any hardware problems.
Hospital Trusts varied considerably in the type and quantity of hardware purchased.
We define “software” as the detailed instructions used to direct the operation of a computer
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to perform a particular task. iSOFT’s Lorenzo, Cerner’s Millennium and CSE’s RiO software
applications were provided to Trusts free of charge as part of NPfIT. One Trust chose to
develop their own additional software at an extra cost. The amount of resource associated
with implementing the national applications depended on a number of factors, including:
• The stage of hardware maturity within the Trust
• The products currently available on the market
• The hardware budget
• The requirements of the application
• The physical requirements of the ward/room.
The stage of hardware maturity within the Trust
Prior to commencing the implementation of EHR systems, some Trusts reported having
hardware of ‘good spec’. These Trusts appeared to be more advanced in terms of hardware,
replacing all keyboards to make them SmartCard compliant when implementing previous
computer systems. One Trust already had a number of computers on wheels on each ward
and reported using them a lot with their current prescribing system. The Director of IT at
another Trust felt the EHR system could be implemented in outpatients with little cost,
recounting how the infrastructure was already in place with a PC in every outpatient clinic.
“…we’ve had to replace the keyboards as per the SmartCard access but we did that when
we did iPM [iSOFT Patient Manager] a couple of years ago, so I don’t think there are any
other significant infrastructure costs” (Interview, IT Manager).
“…virtually every outpatient clinic now has got a PC, all the reception areas are covered with
PC equipment so there’ll be very little cost to actually start to actually roll this thing out into
those sorts of areas’” (Interview, IT Manager).
As part of an ongoing programme ‘to refresh the kit’, hospital Trusts either directly purchased
the hardware from or had a leasing agreement with a technology provider. Synonymous with
their three or four year ‘refreshment’ cycle, the hardware in these different Trusts was of
varying stages of maturity as the finance manager of one NHS Local Ownership Programme
(NLOP) (see Chapter 1) explains:
“Trusts are in different stages of hardware maturity, some have invested, some haven’t (…) I
mean hardware we don’t think is a lot, (Hospital name) and (Hospital name) are largely
modernised (…) they’ve got mobile devices, laptops, tablets. (…) (Hospital name) is
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probably the one that hasn’t got so much investment. But generally all of them have an
ongoing programme of, you know, desktop printer type replacement’” (Interview, IT
Manager).
With this ongoing programme, the Director for IT at one Trust admitted that it was “difficult to
be precise” about what was specifically a cost of a Lorenzo implementation and what was
“just business as usual” (Interview, IT Manager). The project manager at this site outlined
how the purchasing decisions, around the number of computers per ward, came down to the
individual choice of each Trust. In his view, providing each person with a PC on each ward
was not practical. The Director of IT at the same Trust highlighted that ‘space’ was an issue.
Despite having a generous amount of technology already in place on the wards, he accepted
that the current level of technology would not satisfy the demands of ward staff at peak
times. Consequently, he had tried to create more space on the ward in order to provide staff
with more equipment. The Director of IT at a different Trust felt that this rise in demand was
down to the fact that clinicians rarely (if ever) used the previous Patient Administration
System (PAS) system. She felt this rise was to be expected, as they now had to place orders
and check results on the newly implemented Millennium system.
“…some people might decide that 1 [PC] between 10 is fine, some people might decide that
if you don’t have a PC to yourself then you’re wasting your time. So it’s not something you
can give a catch-all answer to I’m afraid. If it was down to me it would be great if everyone
had their own PC but on the wards and stuff like that, that’s not possible’” (Interview, IT
Manager).
“What we do know is the clinicians never used it, they never used PAS so we had 320 users
of PAS on a daily basis at lunch time which is the prime time because you can see them
using it, as soon as we went to Cerner it was 700 and the difference there is the clinicians,
so they’re on it, getting results, placing orders and everything else” ’(Interview, IT Manager).
The hardware products currently available
Another factor influencing Trusts’ decision-making process regarding the type and quantity
of hardware purchased was products currently available on the market. In an attempt to
address the rising demand mentioned above, one Trust chose to increase the number of
desktop PCs by 1 or 2 per ward at a cost of around £2-3,000 in total per ward, and to trial
mobile tablet PC devices sponsored by NHS CFH. The Finance Director of the Trust was
keen to point out that they had “saturate(d) the wards with the tablets” as they “didn’t want it
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to fail because of lack of available resource” (Interview, Finance Director). An IT Manager at
the same Trust illustrated how these devices enabled clinicians to view clinical information
whilst on the move. He later acknowledged, however, that they were very poor for entering
information on and that the Trust had already trialled two different sorts of tablet PCs that, in
his view, were not ‘fit-for-purpose’. The Finance Director also echoed this, stating that they
were too heavy and the batteries got too hot. The third PC tablet trialled was lighter, faster
and allowed clinicians to more easily log in when in close proximity to the tablet PC.
“ So the third one looks quite (…) promising because it’s lighter, it’s faster and it also
supports the proximity card instead of the old chip and pin, instead of the things we all use
now. So that means the clinician can in effect walk up to something and log in by virtue of
being a few centimetres away from it and stay logged in by virtue of being close to it’”
(Interview, IT Manager).
The Director of IT of another Trust expressed how the tablet PCs were “no good”. At a cost
of £1,500 each, she outlined how the device contained a SmartCard slot that did not pass
the infection control standards for her hospital. This was in contrast to the third tablet PC
device mentioned above, which allowed clinicians to log on by virtue of their proximity. She
also explained that the Millennium system has a very busy screen and viewing the
information on the tablet was “nay on impossible”. The length of battery life was also raised
as an issue, and presented in her account as the reason why “you’ll be paying for a new one
in less than, you know, two years” (Interview, IT Manager) if the battery was not allowed to
go flat on a regular basis. She also raised a health and safety issue, explaining that the
tablet PCs got very hot at the back (when in use) and staff could easily get burnt if they did
not hold the device correctly. She felt the devices needed to be further developed.
“…the other thing is it gets very, very hot behind and the concept of those tablets is you put
your wrist behind and there’s a piece of elastic at the back of it and we thought you’d walk
around with it, well if you had your wrist on the back of that you’d burn yourself. (…) Well it’s
just so hot you just couldn’t do it. Now if you hold it around the plastic it’s OK but they’re not
there yet’” (Interview, IT Manager).
As part of the process of implementing Millennium, this Trust had also purchased two mobile
label printers per ward. These devices were just about to be ‘pulled back’ as they were, in
her view, “no good”. She explained how their batteries gradually deteriorated as staff kept
putting them back on charge, a problem similar to the tablet PCs mentioned above.
However, by contrast, she later went on to say that “nobody ever charges them” and the
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label roll needed to be replaced very often.
The hardware budget
The decisions made by Trusts on which type and quantity of hardware to purchase was also
found to be dependent on whether a predetermined budget had been set. One Trust set a
budget of £500,000 to spend on hardware. The Director of IT explained how they could
easily have spent this ‘one-off’ amount “twice over” as the label printers “cost a fortune”
(Interview, IT Manager). One hundred and fifty standard PCs, 100 wall-mounted PCs
(described as standard PCs in metal boxes which were screwed onto the walls), 50
computers on wheels (COWs), and around 300 infection-controlled keyboards at £110 each
were purchased with this budget. The Trust decided to allow each of their 47 wards the
option of choosing between five and eight different devices from the selection of hardware
on offer. The IT manager explained how their team had “tried to be fair” by allowing each
ward an allowance, and insisted that one COW was ‘equivalent’ in worth to three PCs. They
was keen to point out that the infection-controlled keyboards were “a total waste of time”
(Interview, IT Manager) as nobody ever cleaned them within their own Trust.
“We had half a million and then we decided what kit we liked IT wise and we had a COW, a
wall mounted or a normal PC and we said OK come to the shop and that’s what they could
choose and they all chose their own. (…) I think we bought 50 (COWs) and that’s for 47
wards, so some wards haven’t got any and some wards have got three, it’s just what they
wanted.(…) we said you can have between five and eight devices per ward. If you have
more COWs, they are the value of three PCs, so it’s like we sort of allowed them an
allowance and then that’s it” (Interview, IT Manager).
The requirements of the application
In order to run the Lorenzo, Millennium, and RiO applications, local hospital Trusts needed
to ensure that their hardware satisfied certain requirements. These requirements were set
down by the software provider and know as the Warranted Environment Specifications
(WES). For example, tablet PCs were required to have between 512 MB – 1GB of RAM
(Random Access Memory) in order to run the Lorenzo application. The finance Director of
one Trust explained how the memory of 450 machines needed to be upgraded and another
450 replaced in order to satisfy the requirements of the new Lorenzo application compared
to the interim solution (iPM).
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“We put in 450 new PCs or replacements if you like and we upgraded the memory of another
450, and if we’d been using iPM or a thin client system we wouldn’t have had to have done
any of that that was purely driven by the new requirements of the application” (Interview,
Finance Director).
The cost involved in meeting these requirements appeared to be absorbed, in part at least,
by the Trust incorporating them into their ‘refreshment’ cycle (as referred to in the previous
section). By adopting the WES as their standard, this Trust felt that they could guarantee
that the specifications would be rolled out across the whole hospital Trust in four years.
“We upgrade our standard build and any PC, that (…) because of its age or because of a
problem, is replaced by a PC of that spec. So we’re constantly refreshing our estate anyway
and every four years the whole lot gets rolled over and every four years we guarantee that
the WES is met across the whole of the Trust’” (Interview, IT Manager).
However, the Head of IT at another Trust believed that the WES was set too low. She
explained that in order to run the new EHR system alongside other packages (normally
running at the same time e.g. anti-virus), machines would just “grind to a halt” (Interview, IT
Manager). Her Trust ended up spending more on equipment than they had originally
anticipated, replacing all PCs in outpatients after go-live. The Head of IT in a second Trust
also shared this view stating that the WES was potentially ‘flawed’ and the problems with
performance were fixed by his Trust spending more on equipment.
“…they just didn’t spec it out right. What they didn’t think about was the anti virus, the anti
virus sucks power like nobody’s business, all the memory and CPU [Central Processing Unit]
and everything and they didn’t really think of that. So what they said was “you only need this
to run Cerner” which was absolutely true, what they didn’t think about was all the other
factors. (…) So we said one gigabyte has got to the standard for every future Trust going
forward, so we did invest again about three months, four months after go-live we replaced
every PC in outpatients to a faster model’” (Interview, IT Manager).
The physical requirements of the ward/room
Another factor influencing the amount of resource spent on hardware depended on the
physical requirements of the ward or consulting room. With space limited in some wards and
consulting rooms, a wall-mounted computer may be the most suitable choice. However, the
finance director of one Trust admitted that it would be very expensive to put a wall-mounted
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computer in each of the small consulting rooms, and therefore a computer on wheels which
could be shared between different areas might be a less expensive choice.
“…the physical aspect of where you want to put the kit. So some wards, there might be a
desk on a ward that needed a PC so it was really easy, another ward might be really tight
for space so you’ve got to put a wall mounted unit up which is more expensive. (...) If you’ve
got five small consulting rooms and literally a bed and a curtain across the side at the sink
to put a PC on the wall of every room would be very, very expensive so the COW, you’d fit
your clinics out in the morning to suit’” (Interview, Finance Director).
Personnel
Staff were required to carry out a number of concurrent procedures involved in the process
of EHR implementation. These included the accurate transfer of data from the old system to
the new Lorenzo (or interim iPM system), Millennium and RiO software applications (data
migration); the identification and ‘cleaning up’ of any anomalies in the legacy data prior to
migration (data cleansing); the testing of the NHS CRS system post data migration (testing);
the optional procurement and instalment of a wireless network and/or configuration of Virtual
Private Network (VPN) connectivity (networking); the building and testing of interfaces to
integrate software systems (integrating); and training and supporting end users (training and
support). The costs associated with data migration, testing, networking, and training and
support were found to be dependent on a number of factors, as discussed below. We also
touch briefly on the cost associated with a loss of staff productivity (Productivity loss).
Data migration
The costs associated with the process of ‘creating’ data extracts, ‘cleansing’ them, ‘mapping’
them on to the required Local Service Provider (LSP) format, and ‘migrating’ the data over
on to the new CRS system were found to be dependent on a number of factors including:
• The NHS CFH – LSPs agreements
• The hospital Trust - LSP agreements
• The number of systems directly replaced by the new EHR system.
The NHS CFH – LSP agreements
According to the national Approval to Proceed documents, data migration was a cost
attributable to the local hospital Trust. The IT programme delivery manager at one Trust
explained how it was their responsibility to develop the interfaces necessary to migrate the
data to the LSP’s interim system. He described how difficult it was to satisfy the LSP’s
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specific data requirements and populate the tables requested with data extracted from their
old PAS. However, he appeared to take some consolation in the fact that, once the data had
been transferred, it was the responsibility of the LSP to migrate it (from the interim iPM
solution based in their LSP’s data centre) to their Lorenzo system. The hospital Trusts in this
study developed their own interfaces on site, with others reportedly paying an external
company to do all their data migration for them. Checks were also conducted by the Trusts
to make sure that the data were inputted and propagated correctly on output. Despite
recognising the amount of work this involved, the Director of IT at another Trust felt that
moving to the LSP’s interim solution “just makes things easier”, as it required them to think
about their data cleansing earlier in the implementation process.
“In terms of data migration (…), that’s their [LSP’s] responsibility (…) because the [interim
system] sits in the [LSP] data centre and (…) they essentially then do the data migration
from [interim system] to [nationally procured system]. Obviously we have to do the sanity
checks and has it gone in right and is it the right format, etc, and does it come out correctly
as well which is important, but obviously that’s kind of their responsibility whereas before we
had to do all of that. They gave us a lot of tables and we had to populate all those tables
from extracting it from our old PAS and, you know, that was bloody hard work but we don’t
have to do that going forward’” (Interview, IT Manager).
“…even if you go into iPM for six months to kind of skim off it and go into the next one it just
makes things easier because it allows you to bring forward your data cleansing, your Spine
connectivity, you satisfy the requirements around data migration. But the big thing is you’ve
got it in a CSC data centre, boxed up (…) And it then becomes CSC’s responsibility not mine
to migrate it from there into Lorenzo, it’s CSC’s responsibility to deliver all the interfaces that
I had to deliver when we went into iPM’” (Interview, IT Manager).
The hospital Trust – LSP agreements
The costs associated with data migration also related to the specific agreements reached
between the local hospital Trusts and the LSPs. For example, if an agreement was reached
where the data could be migrated in a similar format (the same fields) to that extracted from
the previous PAS system then the costs were likely to be less. However, if there was a need
to obtain additional information from another source then the cost was expected to be
higher.
“…some of the costs would depend, I mean, if it was just the same, exactly the same
records, same fields, you know, but if they wanted some additional information for example
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that we had to pull in from somewhere else that’s where it (the cost) starts to get (high)”
(Interview, Finance Director).
The number of systems replaced
The costs associated with data migration also related to the number of systems directly
replaced by the implementation of the new EHR system. The more systems replaced, the
more data would need to be migrated from the previous separate ‘islands’ or systems (like
maternity, accident & emergency, theatre and laboratory systems) to the new, more
integrated system.
“…you’ve got your main PAS system but you’ve got a separate maternity system, a separate
theatre system, separate lab system, separate GP systems dotted all round over the wider
community. As Lorenzo grows the idea is (…) that Accident & Emergency functionality, that’s
part of Lorenzo, so you don’t need an interface for that, so that’s more integrated. Theatre
system is part of it, maternity system becomes part of it (…) Lorenzo just grows and gets
more and more. So you can do more within the one system so it’s more integrated, more
seamless, more joined up” (Interview, IT Manager).
Testing
Data entered into different NHS CRS systems needed to be tested to ensure that every
component of the system was performing as expected. For ‘early adopter’ Trusts, testing
was viewed as an important requirement as the beta software was, by its very nature, new
and unstable.
“.. we were in effect Beta testing the product so this was a Beta deployment, this was the
first time it had ever been seen outside of India so we had to test” (Interview, IT Manager).
The Director of IT at one Trust recalled the difficulties experienced by her team when testing
their Millennium system. She recognised that it was British Telecom’s (BT) responsibility to
test the system prior to go-live, and sought to demonstrate that their testing had failed to
meet her expectations with different test elements not working when passed to the Trust.
She also emphasised the amount of time the Trust had “wasted” with this, culminating in
them taking over the testing from BT after go-live.
“Well, they did the first element of testing and then they handed it over to the Trust and said
“Over to you now” and then we’d do it after that but I think there is definitely a kick back (...)
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in the first year or so where they'd hand over stuff that you know you could see clearly that
didn’t work and then we just wasted so much Trust time saying “No, that doesn’t work” and
then pass back (...) since go-live we’ve taken on the testing ourselves cause we don’t Trust
them” (Interview, IT Manager).
The IT and Finance Directors’ accounts at another Trust also displayed a lack of Trust of
their LSP’s testing, explaining how their hospital Trust had got “horribly burned” (Interview,
Finance Director) when implementing their interim iPM system because they had regretfully
believed that it was “a robust product” (Interview, IT Manager) that had been tested
thoroughly by the Computer Sciences Corporation (CSC). Based on these experiences, they
recounted how they “wouldn’t let anybody test something as important to us [them] as a
PAS” in the future and so insisted on testing their own Lorenzo system themselves. This
testing was carried out in parallel to the testing conducted by the Single Instance Board for
Lorenzo (SIBL) Group, a group that tests Lorenzo software for NHS Trusts. The Director of
IT reflected on how the establishment of such a group was likely to result in less testing
costs for future Trusts.
“... for a Trust going forward testing is probably an extremely small cost because there’s this
SIBL group, Single Instance Board for Lorenzo and what they’re tasked with is (...)
performing a set of tests at each upgrade to guarantee that that upgrade is fit to deploy for
the rest of the NHS, so the principle being that the rest of the NHS doesn’t have to develop
its own testing expertise and run it’s own testing then have a bun fight at the end of testing
that, you know, “we think it’s good to go”, “we don’t think it’s good to go” so that’s all kind of
handled through the SIBL group. (...) We’re allowed to run it parallel to SIBL so we are
incurring quite a significant cost in testing but Trust B next door I don’t think would be
allowed to do what we’re doing so they would make a saving” (Interview, IT Manager).
Networking
Views varied extensively between Trusts on whether a wireless network was needed as part
of the implementation of EHR systems. The Director of IT at one Trust explained how they
had installed a wireless network from the third floor upwards (where all the clinical wards
were located) but insisted that this was “nothing to do with Cerner” (Interview, IT Manager).
As far as she was concerned, she thought it would be a good idea to put one in at the same
time as putting in Millennium. In contrast, the Director of IT at a different Trust felt very
strongly that a wireless network was necessary and that any Trust implementing the Lorenzo
system would have to put one in (in order to operate the clinical record on the ward). He
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reflected on how they would probably have included the cost of installing a wireless network
in the original business case, if they did not have a solid, reliable wireless network already in
place. This view was shared by the finance director (and project manager) at the same site,
who explained how a “green field” site would have to put one in.
“I would argue strongly the opposite (Wi-Fi is needed) … It’s something we would probably
have put in the original business case if we didn’t have it already, we’d put it in against other
projects, to satisfy other objectives but we couldn’t really be operating a clinical record in a
ward environment without a proper, robust, secure wireless network” (Interview, IT
Manager).
One possible explanation for the difference in opinion between sites may lie in the way that
some interviewees perceived the scope of their new EHR system. The finance director felt it
was possible to run a PAS without a wireless network in place. However, such a network
was viewed as necessary to run an electronic patient record (automating both clinical and
administrative processes): “Could you run a PAS? Yes. Could you run an EPR then I’d say
“no”.” (Interview, Finance Director). The finance manager of one NLOP offered another
perspective, reflecting on how the age and consistency of the hospital buildings may have
influenced their local decision to implement a wireless network. He suggested that it might
be easier to implement a wireless network in older buildings than to hollow out a wired way,
whilst also recognising how some older buildings are prone to weak spots.
“…they’ve got an old building they’ve inherited with a lot of asbestos and stuff and rather
than (…) re-caving in a wired way they’re looking at wireless, but with some of the older
buildings you get problems with weak spots and that sort of thing. But it’s discussed at a
local level” (Interview, IT Manager).
Training and support
There were a number of costs associated with training clinicians and administrative staff to
use the Lorenzo and Millennium systems. These included producing training documents e.g.
manuals, quick reference guides, e-learning materials (Training materials), providing rooms
or lecture-style theatres to teach staff (Training facilities), replacing staff members whilst they
were being trained (Backfill staff), employing / hiring staff to train and support the users
(Trainers, Floorwalkers) and running courses to train the trainers (Train the Trainer). In
addition to the number of users at each site, the amount of resource spent by hospital Trusts
on training depended on the following factors:
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• The training strategy
• The decision to backfill staff
• The level of support
• Trainers’ employment status.
The training strategy
Each hospital Trust developed their own training strategy, consisting of either one-to-one,
classroom or ‘mass’ training sessions, or a combination of the above. The Director of IT at
one Trust recognised how difficult it was to remove clinicians from each ward to participate in
training sessions and so employed extra trainers to coach clinicians and other ward staff on
the ward. One of the ward managers felt that this one-to-one approach (supported by e-
learning disks) was good, explaining how “you can’t pull one of them (trained night staff) out
to do even half an hour of Lorenzo training” (Interview, IT Manager). The IT team also made
a room available close to the ward so that staff could drop in for ‘booked’ and ‘top-up’
coaching sessions. The project manager regarded the establishment of the coaching room
as “one of the best things” (Interview, IT Manager) they did as part of their training strategy.
The Director of IT acknowledged how this had “worked extremely well” for the two wards that
they had deployed Lorenzo in but admitted that it was going to be very difficult for his team
“to sustain that (same approach) across all 55 wards, 2,500 members of staff” (Interview, IT
Manager). To avoid large overheads, he felt that they would now need to take three or four
wards at a time.
“…what we’ve tried to do is come up with a very much blended training strategy, (...) It’s
very, very difficult, in fact impossible to get a classroom full of clinicians out of a ward to train
them. You might get two or three but you’re more likely to get one. So we staffed ourselves
up to, in effect, individually coach people within the ward” (Interview, IT Manager).
He drew a distinction between the different releases of Lorenzo, explaining that the training
required for Release 2 (R2) needed to be conducted in as short a time as possible (over a
10 week period) and as intensely as possible, in order to get the 2,500 members of staff
trained before “go-live”. In contrast, the training associated with Release 1 (R1) could be
conducted over a much longer time period and with varying intensities subject to available
resource. He felt this intense approach for R2 was necessary, reflecting on his experiences
and lessons learnt from implementing iPM (Lorenzo interim solution). During this
implementation, he explained that staff had being trained too far in advance (about 7 or 8
months prior to go-live) with the result that they had “forgotten everything that we’d told
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them” at go-live (Interview, IT Manager). In his opinion, this had been due to the numerous
false go-live dates set and emphasised how they had no time to do top-up training towards
the end. Should the Trust have decided to run top-up training courses prior to go-live, the
costs associated with training would (needless to say) have increased.
“I think the other aspect of training is R1 we can do incrementally and you can speed it up,
slow it down, according to the resource you’ve got. R2 in a 10 week relapse time period
we’ve got to train 2,500 members of staff (...) with iPM we got so many false horizons for our
go-live we started training about seven or eight months before the actual go-live event”
(Interview, IT Manager).
A classroom style training approach was employed at a different Trust. The Director of IT
recounted how they ran ten training sessions simultaneously, each session accommodating
up to 10 members of staff (mainly administrative). She emphasised the enormity of the
challenge in training 5,000 members of staff and the difficulties associated with pulling staff
out of their respective departments for training. According to her, a deliberate attempt had
been made to train clinical staff in all the basics (as well as the extras) by running ‘mass
sessions’ everyday for three to four weeks in a lecturer theatre style. Despite offering
clinicians the freedom to choose any session they would like, she reflected on their poor
uptake (less than half of the clinicians attended the sessions) and how their non-attendance
was, in part, because they just could not be spared.
“I mean we had 10 training rooms running simultaneously with 10 people in each training
course, that’s how big it is (...) it’s massive (...) Not so much clinical these are admin staff
mostly. Clinical staff only did half a day each and then we did mass sessions in a sort of
theatre style to show them extra bits (...) we ran them everyday, half day sessions for about
three or four weeks and they (clinicians) could choose anyone. Some of them did, probably, I
don’t know, maybe 180, but including all the junior docs there’s about 500, maybe a bit more
and so like the rest of them just didn’t, couldn’t be spared” (Interview, IT Manager).
However, six weeks prior to go-live the Director for IT recalled how the outpatient
supervisors voiced their concerns about the training approach employed, explaining how the
training environment (in which their staff were allowed to learn) was not the same as the
hospital build (viewed as more complicated). In her account, she appears to validate the
authenticity of their concerns and change the training strategy such that two trainers would
now be based in outpatients and provide one-to-one training to frontline staff on a copy of
the go-live environment.
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“So what we did we based two trainers in outpatients and brought them out of outpatients
and sat with them and went through it in the cert environment which is a copy of our go-live
even though we were testing it and then they went back to their desk and then we brought
another two [for] (...) one hour, two hours” (Interview, IT Manager).
The decision to back-fill staff
The decision to back-fill staff on the wards varied between Trusts. As part of the training
strategy at one site, the Director for IT acknowledged that a ‘once off’ cost of £750,000 was
spent to back-fill clinical staff. He admitted that this money had come from the Deployment
Incentive Fund (DIF) (see Glossary), but there was an insistence that this was justified.
“…the other big thing that we’ve done is the DIF of one million for R2, we’ve worked out that
three quarters of a million pounds will be required to back-fill clinical staff to support that
training exercise. So straight away three quarters of a million quid’s gone” (Interview, IT
Manager).
The Director of IT at another Trust presented a contrasting view, explaining how no money
had been spent to back-fill staff.
“…if a Trust ever wanted to do back-fill then it would cost millions but no Trust will ever pay
back-fill for that” (Interview, IT Manager).
She reflected on these actions as legitimate, as no Trust in her opinion would ever do this as
it cost too much. This is an important finding, as one might hypothesise that the reason staff
‘couldn’t be spared’ to attend the training sessions in this Trust (mentioned above) might
have been due to the lack of money spent on staff backfill.
The change management lead at a different Trust also raised important concerns over the
availability of staff to replace or ‘back-fill’ those involved in the implementation. In his
account, he drew a distinction between staff roles, highlighting how it would be easier to
replace a member of the administrative staff than a member of the clinical team, due to a
perceived scarcity of consultant specialists.
“…one of the other issues that we found with this just in terms of backfill (...) if I give you an
admin person so (...) I give you [Name] for a day and you give me a hundred quid that’s
great because I ring up Office Angels and they say “No problem. Somebody will be there first
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thing tomorrow morning” works really well. If I give you a consultant psychologist for a day
and you give me a thousand pounds in return which is about the cost for a day of a
consultant psychologist what do I do with the thousand pounds? I can’t get a locum, they just
don’t exist because they’re rare” (Interview, IT Manager).
The ‘hidden’ costs associated with ‘lost’ productivity was also raised in interviewees’
accounts as being a significant cost and very difficult to measure. A deliberate attempt was
made by one interviewee to try and include this cost in his business case. In his account, he
acknowledged how difficult it was to try and calculate the amount of time a person may
spend on other tasks apart from what they were employed to do. Acknowledging that these
costs may be substantial, he was keen to emphasise that he did not want to be “sort of
fuelling that fire” (Interview, IT Manager) that Lorenzo was too expensive. However the
opportunity costs of lost productivity in sites with insufficient back-fill of staff in training is an
important consideration. Simply refusing to back-fill may not, necessarily, be cost-saving.
“I genuinely believe that that is the highest cost that an organisation, a Trust, will encounter
yet it’s something that’s actually very, very difficult to write up in a business case (...) I don’t
have any money to put into their budget to cover it, it’s something that they do often on top of
their other work, if not instead of, but that’s still a real person doing real work, taking real
time it’s not, you know, an entry in the spreadsheet, it’s not a theory, it’s an actual tangible
thing but how do I cost that?” (Interview, IT Manager).
The level of support
The level of support provided to clinical users by hospital Trusts varied extensively. One
Trust chose to support their clinical user base outside normal working hours by extending
their existing service desk to run from seven o’clock in the morning till 11 o’clock at night, at
a cost of £250,000 per annum. The Director of IT was keen to point out that his Trust had
also gone to great lengths to get this service desk accredited through NHS CFH. This meant
that those users seeking help could talk directly to the LSP, thus avoiding the national
service desk established (and later wound up) by NHS CFH. The finance director at the
same Trust considered this advantageous for the Trust, explaining how the national service
desk was “another step between us and (LSP)” and “too far away from the actual operational
role to work” (Interview, Finance Director). Direct access provided them, in his view, with
“efficient first-line support” (Interview, Finance Director). He also emphasised the distinction
between a local help desk, which would typically log the call of the clinician (and call you
back), and a service desk whose personnel would have the specialist skills necessary to
resolve the problem usually immediately. From his perspective, other Trusts were also
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struggling to provide around-the-clock IT support due to financial constraints and felt the
SHA should give more attention to the sharing of services across organisations so as to get
economies of scale.
“…every informatics team I’m aware of runs a nine till five model. Two years ago we put this
to the acute Trust and said what about a 24/7 service, redesign, we’ve got Lorenzo we run
nine till five, I need a quarter of a million pounds to extend my working day to run a shift up
to 11 o’clock at night. So the acute Trust went for that and (…) so they invested a quarter of
a million pounds of their money into my service for me to run from seven o’clock in the
morning till 11 o’clock at night” (Interview, IT Manager).
“…It would be mad to have one acute Trust set up a seven by 24 service with this type of
person at three o’clock in the morning who’s skilled up to know the business processes, they
understand Lorenzo and then 30 miles down the road you’ve got another one, another acute
Trust doing exactly the same thing. And then 30 miles up the road (…) doing the same
again, that’s wrong (…) The service support model is frustrating for me because the
revenue’s not there to go right round the clock and yet I can see organisations right on our
doorstep, on our boundaries, who’ve got the same problem and they’re struggling with
similar budgets and there needs to be some big thinking if you like to get economies of
scale” (Interview, Finance Director).
The funds to support the extension of the service desk’s opening hours in this Trust were
released from no longer providing the maintenance support (now provided by the LSP) for
the newly implemented LSP’s interim solution. This was in contrast to the original PAS for
which the maintenance support was being provided by the Trust.
“…that actually released revenue to the Trust because the national application to the Trust
cost nothing in terms of maintenance contracts. So the previous PAS maintenance contract,
that revenue became available if you like. And some of that allowed me to restructure my
team around this sort of service delivery focus so the seven to 11 working hours and the
dedicated service delivery manager that was all funded out of that revenue stream if you
like” (Interview, Finance Director).
Trainers’ employment status
The amount of resource spent by hospital Trusts also depended on whether the trainers
where employed as permanent or agency staff. As trainers were needed for relatively short
periods, the Director for IT at one Trust noted how “it would be a nonsense for me to employ
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12 people for 10 weeks, well 12 weeks, because I’ve got to train them” (Interview, IT
Manager). The Director of IT at another Trust admitted leaving it too late to go out and recruit
trainers, and reported getting ‘absolutely stung’ by contractors’ fees (a cost of approximately
£500 a day). In her opinion, the recruitment process could take between three to four months
and trainers skilled in using Millennium were in short supply. She also ended up keeping the
trainers much longer (approximately four to six months longer) than she had originally
anticipated after go-live because “it did go so badly” (Interview, IT Manager). In her account,
she argued “every other Trust will get stung by contractors” (Interview, IT Manager). Similar
to other ‘early adopter’ sites, floorwalkers were also provided to this hospital Trust free by
the LSP and NHS CFH to help support users at go-live.
“…we didn’t have time (to) go out and recruit because if you go out and recruit it takes three
months, four months by the time people, and nobody’s got Cerner skills. So what you do you
go to agencies (...) and they charge £500 a day (...) so you immediately doubled or
quadrupled your costs (...) we didn’t pay for the floor workers they paid for all those, BT
Health and Cerner and LPfIT [London Programme for IT] paid because we were first of type
so we had loads of floor workers but they paid for them to stay longer than expected and
then we had trainers probably for another, maybe another four/six months whereas I thought
they’d go off site within four weeks, so we had to invest in those” (Interview, IT Manager).
The Director of Planning in this Trust also described how difficult it was to define the precise
deployment effort and end point of EHR implementation. According to him, the Trust was still
in the deployment stage as they continue to incur start up costs (and are likely to do so for
the next five years), despite having gone live with their Millennium system two years prior.
“... two years in, we’re still, one might argue, in the deployment stage so we’ve still got a
further two years that’s we’ve expended since go-live plus the next five years that we’re
going to expend getting to the point at which we finish the contract doing whatever we do
next so (...) I think actually trying to drawn a black line around deployment effort would be
kind of quite difficult” (Interview, IT Manager).
5.4.2 Phase 2: Quantitative results
Local cost data obtained from Trusts
Of these data obtained, only the actual expenditure data (over several years leading up to
go-live) from two Trusts were used. Projected costs (e.g. from Business Case documents)
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were considered unusable as the interviewees admitted that their compilation had been
‘guess-work’. The data in Tables 5.3 – 5.5 were extracted from reporting: either internal
financial reports, or reports to central bodies such as NHS CFH.
These top-line data can be used, albeit cautiously, to illustrate several characteristics of
implementation costs:
• Different Trusts with different solutions (or different releases) experienced varying
lead-times before go-live
• Different Trusts obtained varying support from NHS CFH and the software vendor.
This support affected resources used (e.g. some sites faced no non-pay costs,
another negotiated complete indemnification)
• Some Trusts (depending upon technological maturity or size) had no capital
expenditure, as discussed.
Table 5.3 contains actual expenditure data from one hospital site, detailing costs incurred
over 6 years leading up to their final ‘go-live’. These data included the implementation of iPM
(interim solution) as part of their overall NHS CRS costs. The key assumptions underlying
these data are as follows:
• iPM majority effort in Financial Year (FY) 2004/05, 2005/06 and 2006/07
• iPM support majority effort in FY 2007/08
• iPM deployment includes initial work with Accenture as well as final deployment
effort once CSC had come on board
• iPM deployment also includes upgrade work, work to upload iPM extracts and
replacement of the High level Data Model (HDM) with purpose built Data
Warehouse integration of iPM with downstream systems and Database System
(DBS) roll-out in 2008/09 and 2009/10
• iPM upgrade to Lorenzo Enterprises (LE) 2.2 in FY 2008/09 and 2009/10 also
roll-out to A&E
• Lorenzo go-live in FY2009/10
• Lorenzo deployment includes ‘early adopter’ work, plus further deployment effort
to support clinical documents, radiology roll-out and pre-work for Pathology.
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2004/05 2005/06 2006/07 2007/08 2008/09 2009/10
Capital
Services 17 52 55 9 11 11
Building/Infrastructure 350 350 350 175 263 175
Other 31 61 86 42 43 45
Contingency
Total Capital 398 463 492 226 316 231
Revenue
NHS staff 253 467 886 534 760 1,555
On-going staff 5 12 27 174 179 187
On-going non-staff
Total Revenue 257 480 913 707 939 1,742
Total 656 943 1,405 933 1,255 1,973
Table 5.3: Local costs for one site (£000s)
Table 5.4 contains both planned and actual expenditure on personnel incurred by another
Site. Key assumptions underlying the planned expenditure data were that:
• All non-pay expenditure would be borne by NHS CFH; there was no capital
expenditure associated with the Lorenzo software and hence no capital charges
arose
• This site employed staff to project-manage implementation and deployment
• Figures include central and SHA support payments where relevant: the DIF of
£1million was obtained by the Trust for deploying software, which had not been
superseded by a subsequent release (Release 1.9)
• NHS CFH, the SHA and CSC provide staff to Trusts to ensure effective development
and implementation of the software. The cost of these staff is included within the
incentive and support payments and shown as a notional income gain for the Trust.
This site did not account for capital costs. However £150,000 was said to have been
allocated to Lorenzo early adoption from within an in-house capital renewal programme (total
spend £600,000), and from which PCs and other hardware were purchased.
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2008/09 2009/10 2010/11 TOTAL Planned
Trust 66 857 332 1,255 720
SHA 6 687 361 1,054
NHS CFH 31 149 56 236 596
CSC 0 0 0 0
TOTAL 103 1,693 749 2,546
Table 5.4: Local costs for the second site (£000s)
Table 5.5: Local financial incentives for the secon d site (£000s)
Interestingly, this shows that this site projected a net surplus from participation in the early
adoption programme. These data also show the proportional levels of support (in terms of
support staff) that this site acquired. However during the process of implementation a
redistribution of workload is apparent, as the final allocations show a large substitution of
local resources for NHS CFH resources. This suggests that an underestimate of necessary
support beforehand led to a need to increase support in this site as go-live neared. In some
sense it may be the case that this implementation was rescued. Moreover, it suggests that
local costs during implementation should not be considered piecemeal to have national
relevance, if the series of the data is incomplete (i.e. does not include (i) actual expenditure
instead of project expenditure and (ii) data covering go-live). In general, this site committed
around 50% of the personnel resources locally, with the remaining 50% being provided
centrally. This reflects the findings of qualitative data discussed previously.
5.4.3 Contextual findings
In their updated systematic review, Goldzweig et al. remark that there is a dearth of literature
that considers contextual factors and process-changes relevant to the implementation of
2008/09 2009/10 2010/11 TOTAL
SHA 82 526 4 613
NHS CFH 109 652 20 780
CSC 0 294 294
Incentive 1 9 1,000 1,000
Incentive 1.9 250 750 1,000
Total Notional Income 1,441 2,222 24 3,687
Net Project Cost 1,095 -612 -244 239
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multi-functional health IT systems.(19;151) In our study we found that these contextual
factors are very important. Hospital Trusts were found to have received asymmetric levels of
central support during early adoption; some Trusts received more support at acute periods
that coincided with the attainment of NHS CFH set go-live targets for different software. In
some cases the development of the software was in parallel with implementation; delays in
development meant cost overruns, learning loss at hospital Trusts (who then required re-
training) and a loss of momentum generally.
The effects of these factors on the timeliness and cost of implementation were substantial,
and on our evaluation, were that ordinarily clear relationships between implementation and
costs such as scale, baseline levels of personnel and capital/IT, baseline efficiency, etc.
were largely obscured by the process itself. However, it is important to note that this does
not imply that the technology itself is, prima facie, ineffective: our evaluation was of early
adoption, which, by definition, entails a learning curve.
5.4.4 Integration of results across Phases 1 and 2
Cost-sharing
During early adoption responsibilities surrounding implementation appeared to be shared
between the hospital Trust, the SHA, NHS CFH and the software provider. In principle:
• Software/license costs were borne by NHS CFH (who had currently commercial-in-
confidence contracts with the suppliers)
• Testing was the responsibility of the supplier (although some Trusts did their own
testing)
• Hardware and local infrastructure were the responsibility of each hospital Trust
• Data backup, integrity and recovery were the responsibility of the supplier
• Training, including floorwalkers, was the responsibility of the Trust (although it
appears from the qualitative findings that this was shared with the NHS CFH, SHA
and supplier).
There was variation across Trusts, with some finding central resources e.g. floorwalkers,
‘pulled’ from one Trust to another. One Trust, as a result, incurred substantial costs hiring
contract floorwalkers. This is a phenomenon that is likely to be observed during a national
roll-out, whether centrally-procured or devolved; particularly as consortia or consulting firms
will be likely to emerge in a larger market.
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The NLOP attempted to organise a training pool, whereby trainers were procured based
upon need across hospitals, and then train across sites. However they found that holding a
large pool of trainers was insufficiently flexible and costly: the single accommodation site
faced the burden of hosting, while transport and local accommodation proved difficult also.
Moreover training resources were lost due to scheduling problems, and individual Trusts
ended up procuring (and paying for) their own training anyway. With Trusts seeking lower
costs through locally integrated procurement, this phenomenon is also still possible during a
national roll-out.
As discussed above, one Trust decided to carry out its own testing alongside that provided
by CSC. This Trust also had been developing their own software to run on Lorenzo to solve
operational problems locally, further generating local testing needs. Since all Trusts can
feasibly be in a position to development local technological solutions, there is some potential
for this to occur in the future. However, local software development is not perceived to be a
necessary aspect of implementation of the NHS CRS. Therefore, costs incurred through
further development locally are at the risk of each Trust.
Similarly, one Trust contained their own back-up/disaster recovery systems, at their own
cost, despite the availability of central servers and central data back-ups. This was their own
decision; however it may be that individual Trusts have their own regulatory conditions that
determine whether or not such contingency plans need to be in-house.
For future Trusts, which may have to support implementation costs entirely locally, this
suggests that previous experience was based upon some autonomy varying degrees of
support centrally. Thus the actual decisions made may not reflect optimal decisions if each
Trust were solely responsible for costs. The results for the second site, for example, show
that support had to be increased substantially just before go-live; however, local under-
resourcing could have been a result of the knowledge that central resources were available.
Costs in a fully-devolved national roll-out
The future information strategy, to be published following consultation on the government
White Paper Liberating the NHS: An Information Revolution will define the vision and roles of
the NHS Commissioning Board and the Department of Health (DH) in setting clear national
informatics standards for the NHS.(14) It is likely to propose devolving responsibility for
procurement and purchasing of IT systems to Trust level (based upon pre-election
commitments to halt and renegotiate NPfIT contracts).(14) This opens up substantial
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uncertainty for Trusts around:
• Current prices paid for software licenses (as contracts between NHS CFH and
software vendors, based upon expected user-numbers at the SHA level, are not
known – either to the Trusts or the researchers). Moreover, prices will vary, as some
hospital Trusts will be able to procure as a bloc, enjoying monopsony purchasing,
whilst others will not.
• Current prices reflect not only negotiation but also functionality. For example,
Millennium is not a single, built product. Higher functionality will be more expensive,
however: (i) each hospital Trust may need different degrees of purchased
functionality, depending upon the services they provide; and (ii) hospital Trusts will
have autonomy over how large a scale of solution they purchase.
• Software providers or NHS CFH provided several distinct services to ‘early adopter’
Trusts. These included data migration for some circumstances in some NHS CRS
solutions, backup and disaster recovery, and varied personnel (including
floorwalkers, trainers and change management expertise). As a result, neither future
levels nor unit prices of these aspects of implementation can be known.
• As mentioned above, information was obtained that alluded to conventionally
understood levels of support. For example, in Table 5.5, the second site appeared to
receive approximately 50% support in terms of staffing, from other sources (NHS
CFH, the SHA and the software vendor).
NHS CRS solutions, ‘big-bangs’ and ‘soft landings’
During early adoption there were several dimensions of heterogeneity that introduced very
different experiences for hospital Trusts.
‘Big-bang’ versus ‘soft landing’
The so-called ‘big-bang’ implementation (see Chapter 3) is defined as combining the
implementation of the NHS CRS application, including all of its functions, and re-designed
workflows, simultaneously.(161) The ‘soft landing’, by contrast, is a phased implementation,
ideally wherein each phase is supported by its own training, analysis and go-live – thereby
allowing manageable training and process change loads through the organisation. For
example, the second site (Table 5.5 above) underwent a ‘big-bang’ approach when
implementing their interim solution (iPM) and subsequent Lorenzo (Release 1.9). This Trust
also chose a ‘soft landing’ approach for certain deployments because it did not require a
site-wide implementation. In a study by Culp et al (2006), they also experienced both in a
general practice setting.(163) They found that ‘big-bang’ implementations created practice
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chaos, as there was an inability to absorb training and substantial productivity losses. This
led them to moving to phased implementations.
An important distinction between the phased and ‘big-bang’ implementations however, is
functionality. Although this was not explored by Culp and colleagues, it is the case that: (i) a
phased implementation may be feasible because the system has lower functionality than
one requiring a ‘big-bang’ implementation; this will naturally suggest lower costs in terms of
productivity loss and changed workflows; and (ii) a ‘soft landing’ implementation, of lower
functionality, will not necessarily forestall a later ‘big-bang’ implementation once higher
functionality is released. In the case of NHS CRS implementation these are important
distinctions, because the software implemented varied in this regard.
First-movers with ‘big-bang’ implementations – where the ‘big-bang’ was necessitated by
functionality – appeared to suffer the most. Subsequent movers, even with largely the same
functionality and ‘big-bang’ implementation, on the other hand, already benefited greatly
from lessons learned by observing the first movers. Unlike negotiated prices, then, there is a
first-mover disadvantage with respect to the losses of productivity and workflow, cost over-
runs, etc. Other Trusts, for example, suggested that their own ‘big-bang’ implementation was
preferable.
Lorenzo, Millennium and RiO
We found that none of the systems was in functional equipoise with another: for example,
implementation of Millennium, similar to Lorenzo’s interim solution (iPM), necessitated a ‘big-
bang’ implementation, because it was initiated with functionality that could only be
implemented site-wide. Indeed, all Lorenzo sites piloted the beta software in only a few
wards initially.
This does not mean, however, that one or the other was more costly. As discussed, first-
movers in ‘big-bang’ (Millennium) implementations experienced significant induced costs;
however subsequent movers experience more stable implementation. At the same time,
Lorenzo implementations amongst ‘early adopters’ only delayed a ‘big-bang’, as iPM
required, and before phased implementation of lesser releases had permeated Trust-wide.
More importantly, there is some evidence that Millennium only front-loaded a steeper, but
foreshortened, learning curve; this learning experience might then be much longer in
Lorenzo implementation sites as the software is developed and more applications are
integrated into practice over a longer period of time.
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The effect is that, for Lorenzo, there is less first-mover disadvantage compared with
Millennium, but subsequent movers could suffer greater induced costs relative to those with
Millennium. The net effect across a cohort of implementing sites is not currently known, as
insufficient Trusts were in the ‘early adopter’ programme, and comparable implementation of
Lorenzo (i.e. to completeness of functionality) has not yet occurred.
Timeline of up-front and recurring costs
The relative scale of start-up costs compared to recurring costs, and the associated duration
and distribution of each, is still questionable. This is due to varying delays in implementation
and consequent lack of available data: none of the systems, or their implementations, has
reached a state of stable maturation. All data should therefore be considered to represent
either start-up costs, or potential recurring costs – but not stable recurring costs.
Due to the observed differences between projected and actual start-up costs in the few
Trusts with data, there is also no evidence that projected recurring costs could be used
reliably – particularly with regard to evolving government policy around NPfIT contracts. This
also applies to differences between start-up and running costs between different NHS CRS
systems.
5.4.5 The Minimum Data Set (MDS)
One of the main outputs of this evaluation is the MDS (see Appendix 17), which we hope
gives a useful steer to Trusts planning to implement the NHS CRS to ensure that they have
a robust costing model. It can also be used as an evaluation tool to collect the minimum
sufficient information (at hospital Trust level) to contribute to future cost-effectiveness and
cost-benefit studies of IT.
We consider hospital Trusts to be multi-output producers: they utilise a wide range of
resource at the same time to produce a wide range of outputs, but in a single joint process,
rather than in parallel processes. As such, they employ a complex production process. This
makes it difficult to isolate and quantify NHS CRS implementation costs in terms of induced
costs in a post hoc evaluation. At the same time, the hidden nature of much of the resource
use and pricing, through central contract with software suppliers, largely obscures much of
the direct system costs. With this tool, we expect that the critical costs incurred during an
EHR implementation, including system costs and many induced costs, can be collected.
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With adequate trialling of technologies, residual induced costs such as productivity losses
due to learning curves and differences in task completion time can also be collected.
The MDS was constructed in a completely secular manner, with respect to the NHS CRS
solutions, and it’s content validated for all NHS CRS systems, all implementation types
(whether phased or ‘big-bang’) and hospital trust-types (NHS or Foundation; mental health
Trusts, teaching etc.; and of varying sizes). For the purposes of a national roll-out of the
NHS CRS, we believe that our mixed methods approach was desirable.
In terms of operational feasibility, however, there remains a question over the utility of the
tool. In particular, the tool does not overcome the underlying complexity of the production
process at hospital Trusts. Therefore, completing the tool in a hospital Trust while it is
undergoing NHS CRS implementation is going to be time-consuming, and a technical
challenge in itself. We also note that the MDS may be incomplete in measuring
implementation costs, specifically opportunity costs of: (i) lost productivity through under-
resourced training; and (ii) lost-productivity through learning. We are not aware of data that
could practicably be included in the MDS to capture this; however complementary
time/motion studies, for example, may be useful.
5.5 Policy implications and recommendations
Our evaluation identified and categorised the potential costs associated with the
implementation of the NHS CRS amongst ‘early adopter’ hospital Trusts, as discussed in
Section 5.4 of this report. We also believe that our evaluation has succeeded in detailing the
complexities of decision making processes involved in hospital Trusts, and the contextual
factors within those that affect the implementation costs of a comprehensive IT system. Any
nationwide roll-out requires careful establishment of evaluation criteria beforehand. This has
led to the operationalisation of our cost framework in a MDS. This MDS is an evaluation tool,
generating the minimum sufficient information to allow Trust-level cost-effectiveness and
cost-benefit studies to be undertaken alongside a nationwide roll-out of the NHS CRS.
We strongly recommend that prior to implementation of the NHS CRS nationally this MDS is
embedded within the process. This will enable a robust evaluation of implementation costs,
including direct, indirect and induced costs.
We also note that there is limited value to centrally-funded and mandated evaluation of any
IT systems or their implementation, based upon incomplete information. It is, therefore,
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essential that such data includes all data on costs – including commercial and other
contracts. These data were not made available for this evaluation, which has limited the
conclusions that we could draw.
5.6 Future research
Several previous systematic reviews have commented upon the complexity of the production
process within the healthcare system.(19;151;164) However, broad health technology
continues to be evaluated either as a technology with narrow reach, or as a technological
change within a single-output producer. Our evaluation of the early adoption of the NHS
CRS has shown that there is substantial scope for research that captures a system-wide
perspective on costs. We believe that data can be generated during the process of
implementation – on both benefits and costs – that generates sufficient information for a
complex evaluation. Future research should focus on hospital sites where the technology is
more embedded to establish the long-term recurring costs which were very difficult to
ascertain in the timescale of our project.
The NHS CRS, within NPfIT, is the largest health IT/Informatics programme to have be
attempted anywhere in the world. It is also the largest, purposive technological change
imposed upon such a complex national system. It is therefore of critical importance that
robust programme evaluation be performed. Our MDS is a tool by which the critical costs
incurred during NHS CRS implementation can be collected. However, further important work
is required to assess the acceptability, technical feasibility and validity of such a tool, as well
as the completeness of the data it will provide, particularly with regard to opportunity costs,
which are not routinely observable or measurable.
Finally, we believe that, due to the size and scale of the Programme, the process of
implementation itself should be explored and used to contribute to evaluation processes and
tools, including information sufficiency. This knowledge could also be invaluable to future
policymakers and researchers.
5.7 Discussion
Our evaluation has established the cost framework: using microeconomic production models
to identify domains of inputs that could be affected by a broad-reaching technological
change within a hospital setting (e.g. EHR), followed by a pragmatic search for financial,
planning and other resource-use documents from hospital Trusts in order to attempt to
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specify inputs within those domains that were employed in implementation. This framework
was operationalised in a MDS, which functions as an evaluation tool and generates the
minimum sufficient information (at the level of the hospital Trust) to contribute to future
robust cost-effectiveness and cost-benefit studies.
5.7.1 The cost framework
Key infrastructure variables were found to be: the degree of IT maturity within the Trust; the
EHR products already on the market; the IT hardware budget at the Trust; the requirements
by the Trust of the IT application; and the physical requirements of the operational space
(e.g. wards, clinics). Infrastructure costs and personnel costs were found to be most
substantial. The former were likely to be determined locally and reflect a range of hospital
Trust characteristics: scale, level of penetration and current place in what was identified as
an IT/hardware renewal cycle. Key personnel costs related to: data migration; testing;
network; training and support. Two factors in particular impacted on training costs: the
approach taken by trusts and the decisions made around whether or not to back-fill staff.
Key estates costs included IT equipment and space to accommodate activities within
implementation, such as: project management, data migration, integration and testing, and
training, as well as IT management and clinical/administrative support. Unlike some of the
other costs, estates costs are more likely to be directly generated by scale. This means
increasing in terms of the scale of the applications (i.e. increasing in complexity as more
project management, data migration and other roles are needed) and increasing in the scale
of the hospital (principally generating an increase in IT management, clinical and
administrative support costs, reflecting a greater number of personnel and computers).
Although miscellaneous costs were generally broad (consumables and training material, for
example), the most relevant identified by Trusts overlapped with other domains: servers for
data migration and cleaning, interfacing, and rehearsal prior to go-live.
5.7.2 Endogenous cost-drivers
Some of the cost-driving decisions made by ‘early adopter’ Trusts were seen to be
endogenous to aspects of the implementation itself, and therefore not representative of a
national roll-out of the NHS CRS. The principal financial incentive was the DIF from the LSP.
In one of the smaller Trusts, DIF money paid to the Trust was a deciding factor in early
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adoption: without that capital, adoption of the NHS CRS would not have been feasible. In
another Trust, we found that DIF money, even though it was larger in amount compared to
the former example, had not been a factor in the implementation decision. However it was
instrumental in the decision to back-fill staff, thereby taking an implementation strategy that
would not otherwise have been considered. Therefore, this Trust’s personnel costs were
large, but also not reflective of their approach without the DIF.
Other incentives were driven by within-implementation pragmatism. Throughout, ‘early
adopters’ enjoyed models of cost-sharing with NHS CFH, their SHA and the software
providers. The proportions of these varied by Trust but, in general, Trusts incurred around
50% of the total implementation costs. However there were two exceptions to this: the first
was when, during the period, some hospital Trusts became critical to central policy
benchmarks on the NPfIT and the NHS CRS. At these times, substantially greater resources
were assigned to those Trusts, thereby altering both progress and costs out of the otherwise
generalisable framework. The second related to some trusts individually negotiating cost-
shares out of the norm.
These factors suggest that both the pace and related cost of implementation were both
greater than an autonomous trust might experience, even though the nature of the resources
used and the costs incurred will be the same. Also, these Trusts did not have the chance to
learn the valuable lessons from the implementations at other Trusts.
In ‘early adopter’ hospital Trusts for which costs were available, they followed a similar
pattern in the periods before go-live: higher initial costs, lower costs and then escalating
costs again leading into and during go-live. This reflects front-loading investment and
project-initiation costs, with a levelling-off during training and product development and
piloting. Go-live then involved site-wide staff at all levels, including project management.
This distribution in timing does not reflect running/ongoing costs of the NHS CRS itself, only
the distribution of start-up costs leading up to activation of the NHS CRS on-site. In fact, one
site articulated their position that start-up costs were still characterising their experiences,
over two years post-go-live, as the system had still to be stabilised across the organisation.
This distribution however is understandable and should be experienced elsewhere. Some
variation in term of personnel costs will be experienced depending upon the decision made
with respect to training (e.g. back-filling staff will likely generate steadily increasing personnel
costs throughout).
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A precise, proportional comparison of capital costs and labour costs was not available in our
data. This largely reflected the lack of financial information, which was also a function of
cost-sharing: central contracts (e.g. between NHS CFH and software providers) was
commercial-in-confidence. So, too, were levels and prices of resources supplied to Trusts
within these arrangements.
In general, however, Trusts all found that personnel costs exceeded capital costs by a
substantial factor. However this was potentially an artefact of central contracts for NHS CRS
licenses – which, being commercial-in-confidence, were not shared. This is a critical lack of
data however, because it prevents extrapolation to a decentralised contracting environment:
license costs can be substantial; moreover, NHS CRS product costs are not singular, but
reflect the total functional add-ons associated. Therefore some Trusts will pay more than
others if they (a) have more staff and/or (b) demand greater functionality; some Trusts will
inevitably still purchase software as a monopsonist bloc while others will not, and enjoy
lower costs.
The level and variation in these costs is not currently available. What information is
available, through interviews and public information, suggests that contracts to providers
may have been £36m per deployment in the South of England (covering licenses and
deployment support). One interviewee estimated that an independent hospital Trusts
purchasing NHS CRS software systems would on average pay £25-£30m, increasing to
£50m for a large hospital Trust.
5.7.3 Contextual findings
Although NHS CRS early adoption is a single programme there were, inter alia, intersecting
pressures within the Programme, and NPfIT, at the same time. First among these was
political pressure applied to the DH and then, in turn, to NHS CFH and NPfIT, as well as
software suppliers, to demonstrate progress on deployment of the NHS CRS after it had
stalled. Reasons for the delay included: development of systems in situ; and withdrawal of
vendors from NPfIT in the South of England. This led to ad hoc allocation of resources in a
manner of response mode: this temporarily inflated resources in some Trusts (e.g. supplying
extra staff), while also curtailing the resources to other Trusts at the same time. In our
evaluation it was impossible to isolate these events (partly due to their dynamism; largely
due to no data on central resource and decision-making) and separate their effects from the
underlying experience of implementation costs at Trusts.
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Three NHS CRS systems were included in this evaluation: Lorenzo, Millennium and RiO.
However, during the evaluation different releases, with different functionality, were observed.
This means that a given build of Millennium was not likely to be functionally equivalent to a
contemporaneous build of Lorenzo or RiO. It also meant that two Trusts, each with Lorenzo
but with different releases, cannot be compared directly – such is the impact of functionality
on costs of implementation.
In a related way, we observed distinct differences between phased implementation and ‘big-
bang’ implementation. However some critical characteristics of implementation type are
important. First, there were not enough of either type to establish an average cost for one or
the other. Secondly, a phased implementation (a) is not everywhere feasible (e.g. site-wide
implementation of Millennium forces a ‘big-bang’ implementation) and (b) will not necessarily
prevent a ‘big-bang’ (e.g. Lorenzo without iPM can be piloted and phased in; iPM is still a
‘big-bang’ implementation). Because ‘early adopters’ still have not completed site-wide
implementation and stabilisation of the NHS CRS for all of the three client solutions, the
overall costs also cannot be compared.
Our analysis identified gaps in the literature relating specifically to complex and contextual
elements of broad EHR implementation in the healthcare settings. These gaps were also
discussed as limiting factors in robust cost analysis of EHR implementation in hospitals,
which are complex organisations with multiple, interlinked outputs. In response to this our
cost framework was specifically developed in a flexible manner that initially was based upon
relevant production theory, then expanded, completed and validated through repeated
consultation with hospital Trusts and individuals at all available levels.
5.8 Conclusions
The MDS was identified as the minimum sufficient information for a robust analysis of
implementation costs. With the MDS, site-level data on costs in each of the relevant fields
can be collected prior to, during and following implementation, including identification of
relevant benchmarks in the process. However, such data must be supplemented by
information on costs contained within contracts which was not made available to us in this
evaluation. This will facilitate cost-benefit and cost-effectiveness analysis of nationwide NHS
CRS to be done. Since the NHS CRS is the largest and most complex EHR implementation
of its kind in the world this will no doubt prove to be invaluable, both internationally and for
future technological growth in England (and the UK), both in the public and private sectors.
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Chapter 6: Availability of clinically important inf ormation in
outpatient clinics
6.1 Introduction
Electronic health record systems have the potential to improve availability and accessibility
to patient records. Missing information can, for example, potentially compromise the quality
and safety of care and also introduce inefficiencies in care provision. The original aim of this
work-package (WP) was to investigate whether the introduction of the NHS Care Records
Service (NHS CRS) in England resulted in an improvement in availability of a variety of
clinical records and clinical test results in secondary care settings. We hypothesised that the
introduction of the NHS CRS would improve:
• Medicines reconciliation on admission to, and discharge from, hospital
• Availability of clinical records in outpatient settings
• Availability of clinical test results in secondary care outpatient and inpatient settings
• Discharge communication from secondary care.
In light of the substantial delays in the national roll-out of the NHS CRS in general and
clinical functionality in particular, it became clear that it would not be possible to address all
of the objectives because of the lack of opportunity to obtain “post-implementation” data. It
was, therefore, decided to focus on studying the completeness of clinical information in
outpatient settings as we had reason to believe that potential changes in response to the
implementation of the NHS CRS would be observable within the timescale of this evaluation.
Research on the completeness of medical information in NHS outpatient settings is scarce.
Limited information is based on surveys of hospital staff.(48;165;166) The first survey
conducted by the Audit Commission involved 225 respondents from 40 hospital Trusts who
reported major problems including difficulties in retrieving records for consultation, poor
quality of record-keeping within the case-note folder and poor facilities for storage of records.
At the time, only 75% of the Trusts surveyed met the 95% benchmark for availability of
patients’ medical records at outpatient clinics as set by the Audit Commission.(165) Some
improvement was seen in a follow up study in 1999 with an increase in the national average
availability of medical records from 96.0% to 97.3% between 1995 and 1999.(48) A more
recent study found that missing clinical information affected around 15% of surgical
outpatient appointments (95% confidence interval (CI), 12.9, 17.1).(166) These findings are
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not directly comparable with the Audit Commission study as a wider range of types of
missing information was considered.
6.2 Aims and objectives
We aimed to investigate whether the introduction of the NHS CRS in England resulted in an
improvement in availability of clinical records in secondary care settings.
More specifically, we sought to:
• Determine the proportion of outpatient encounters where there was at least one
clinically important item of information missing i.e. information required by the
clinician at the point of contact with the patient in clinic.
• Determine the frequency with which particular types of information needed by the
clinician were missing.
• Determine whether the introduction of elements of the NHS CRS resulted in changes
in the proportion of outpatient encounters where clinically important information was
missing.
• Identify the contextual background of these findings.
6.3 Methods
6.3.1 Design
We employed a combination of quantitative and qualitative approaches in this WP. We first
undertook a cross-sectional study in which we measured the completeness of medical
records in outpatient departments in four NHS Trusts prior to the introduction of the NHS
CRS and then followed this with a controlled before-and-after study of the completeness of
outpatient medical records following the introduction of elements of the NHS CRS in one
NHS Trust when compared with a matched control Trust. We in addition undertook a
concurrent qualitative study including observations and interviews to support the
interpretation of quantitative data (see Appendices 18-20 for information sheets and topic
guides).
6.3.2 Setting
Data were collected from NHS sites in England that were working towards implementation of
the NHS CRS.
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6.3.3 Sample
Recruitment
Members of our research team assigned to the various recruited sites (see Chapter 3) asked
senior NHS management if they were willing to participate in this aspect of the evaluation of
their outpatient departments. All the sites approached were intending to “go-live” with some
elements of the NHS CRS during the timeframe of the evaluation.
We aimed to recruit a broad distribution of sites from different areas of the country, and of
the six participating sites approached, four agreed to take part in this out-patient evaluation.
All four of these sites participated in the cross-sectional evaluation to assess the frequency
of missing data in out-patients clinics.
For the controlled before-and-after study, one Trust implementing an element of the NHS
CRS within the timeframe of the study was selected as the intervention site. This
implementation had potential to impact on the outpatient department as it replaced iPM with
the Lorenzo Patient Administration System (PAS). The elements of this software included:
• Referrals
• Access planning
• Patient Identity
• Personal Demographics Service (PDS)
• Outpatients
• Caseload Management
• On-Link linkage to Picture Archiving and Communication System (PACS) Images
• Interaction with Choose and Book.
One Trust with similar baseline levels of incomplete data in the outpatient department was
used as a control.
6.3.4 Data collection
Design and pilot
We developed a questionnaire based on observations and consultations with Healthcare
Professionals at a London Teaching Hospital in June 2009 and it was re-piloted later with
seven consultants for 133 consultation events at a District General hospital from July to
September 2009 (see Appendix 20).
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Data collection process
Senior managers at participating sites were provided with information about the outpatient
evaluation. Later, meetings were scheduled (if requested) to discuss this aspect of the study
in greater detail. The data collection form was designed to make it quick and easy for
participants to complete in busy outpatient clinics. Participants were asked to tick the various
response options on the form depending on whether clinically relevant information was
missing or not. A definition of the terms used in the questionnaire is shown in Table 6.1.
Table 6.1: Description of the items described on th e data collection form
Data collection took place in the outpatient departments of the participating Trusts between
May 2010 and December 2010. If a Trust had more than one hospital site, then the main
(adult) outpatient departments were selected.
Clinicians were asked to fill in one questionnaire per patient in each clinic. Data collection
took place mainly during morning and afternoon clinics along with an occasional evening
clinic. Prior to data collection, the purpose of the study was explained to the clinicians and
details provided on what they needed to do. The researcher was available to deal with any
questions about the study from the clinicians and members of clinic staff.
Before data collection commenced at each clinic, the researcher noted the clinician in
charge, the type of clinic (e.g. urology) and the number of patients expected to attend. Each
clinician was given a number of questionnaires equalling the number of patients expected to
Section Examples
Medical Case Notes Clinically important medical records
Referral Letter New patient generated letter via Choose & Book or direct from
the GP
Imaging results X-rays, MRI, etc
Monitoring results 24 hour blood pressure / heart monitoring, etc
Lab results Blood results, etc
Reports ECG, rehabilitation notes, etc
Addressograph labels labels to send off for diagnostics
Other Operation notes; last clinic notes; letters to GP; history
information, etc
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attend. Throughout each clinic session the researcher remained close at hand to answer any
queries that arose, checking on how the forms were being filled in, providing more forms if
extra patients had been added to the clinic as well as observing the processes and activities
taking place.
At the end of each clinic the questionnaires were collected and staff asked if any problems
had arisen in completing the forms. The total number of questionnaires handed out and
returned at every clinic was recorded by the researcher.
For the qualitative study during the data collection process the researcher remained in the
outpatient departments making observational notes. At each site, staff were asked if they
could be interviewed. Those interviewed included managers of medical records libraries and
the outpatient departments, clinicians in the outpatients department and other relevant staff
when necessary. The interviews were digitally recorded and the staff received an
undertaking of anonymity. The aim of the qualitative study was to explore issues relating the
completeness of information in outpatient clinics and the potential impact of implementation
of the NHS CRS.
The researcher was informed that the staff in Site X were too busy to fill in a form for every
patient; it was therefore agreed that they would fill in the questionnaires when clinically
important information was missing and would report on the number of encounters where
either there was no missing information or staff had not had time to check. This process was
monitored regularly by the researcher throughout the clinic and at the end of the clinic the
results were re-checked with the staff.
Data processing
The first step in this process was to input all the data collected into a specifically designed
Microsoft Access database which mimicked the form for ease of entry. Each item of inputted
data was then checked for accuracy by referring to the original data collection forms. Very
few errors were detected and these were all corrected.
The database was then transferred to a Microsoft Excel spreadsheet where the data were
anonymised, then exported to STATA Version 10 for further analysis and finally to a PROC
GLIMMIX within SAS®.
206
The interviews were transcribed, anonymised and uploaded on to NVivo8 for further
analysis.
6.3.5 Data analysis
The main outcome variable in this study was the proportion of patients with at least one
piece of clinically relevant information missing. The frequencies and percentages of this
variable were calculated before and after implementation of elements of the NHS CRS. In
addition, frequencies and percentages were calculated for specific missing items. These
included referral letters, images, monitoring information, laboratory results, addressograph
labels, medical notes and other unspecified information. Results were reported for each site
and for the entire dataset.
In addition, for those records with clinically relevant information missing, it was established
whether information was obtained during the course of the clinic, and whether this caused a
delay. The median delay (and inter-quartile range and maximum) due to missing information
was calculated. Also, the proportion of patients who required further investigations or
another clinic appointment was also calculated if this information was available.
We have provided 95%CI for the percentages of outpatient encounters with missing data.
For the cross-sectional study, these are presented for each of the four Trusts. For the two
Trusts included in the controlled before-and-after study, the ratio of the odds (OR) of missing
data in the two periods have been calculated together with their corresponding 95% CI.
Finally, the ratio of these ORs for the intervention and control Trusts have been calculated
with 95% CI. As there are differences between clinics within Trusts in the percentages of
outpatient encounters with missing data, standard statistical methods based on assumptions
of independence of the observations are not valid. Instead, generalised linear mixed models
have been fitted using a logit link, with clinics within Trusts fitted as random effects. In the
cross-sectional analysis, the method has been used to provide an appropriate inflation in the
standard errors, with the CIs centred on the observed proportions. In the before-and-after
study sites, periods and their interaction were fitted as fixed effects, together with type of
clinic. Analysis was performed using PROC GLIMMIX within SAS®.
Observations and interviews undertaken in outpatient clinics and medical records
departments are in the process of being analysed qualitatively. Detailed findings from these
will be reported in due course. For this report, we have drawn upon emerging findings
insofar as they help to explain the main results of our quantitative analysis.
207
Sample size considerations
Conventional sample size calculations to achieve pre-determined power to detect changes,
either within a site or between intervention and control sites, could not be calculated as there
was no information on the extent of between-clinic variation within site, or variation between
sites. In practice, the sample sizes were determined by practical consideration of which sites
were available for study and the available resources for the surveys. As many clinics within a
site as was logistically possible were sampled to minimise the effect of between clinic
variation on the precision of the error rate for a site.
6.4 Results
6.4.1 Cross-sectional study of four sites
Table 6.2 shows details of the sites that participated in this study. There was a wide
geographical spread of Trusts although three sites were from the North, Midlands and
Eastern (NME) cluster and one from the Southern cluster. The sample included smaller
district general hospitals and larger urban Trusts. Some were single sites, whilst others had
multiple sites although only large outpatient departments were surveyed in each Trust.
A range of outpatient departments at these sites covering many aspects of care including
general medicine, general surgery, obstetrics & gynaecology and orthopaedics, were
evaluated. A large number of clinicians were involved in the study. The researcher was
based in each of the outpatient departments for a period of between three to nine days.
In the evaluation, a total of 2,897 forms were given out to 150 clinics throughout the four
Trusts. Of these, 2,537 forms were returned giving an average response rate of 86%.
208
Table 6.2: Details of the Trusts that participated in the study
Table 6.3 shows the overall proportion of outpatient encounters with at least one item of
clinically important information missing. This varied from 7.9% at Site C to 17.6% at Site B.
There were instances where more than one item was missing with some patient encounters.
Table 6.3: Proportion of outpatient encounters with at least one item of clinically
important missing information from the cross-sectio nal study
Site
L C X B
Number of hospitals
surveyed at each site 3 2 1 3
Cluster South NME NME NME
Approx number of
beds 700-800 1000-1100 300-400 1000-1100
Number of clinics
selected 50 21 39 40
Number of separate
types of clinics 22 11 14 17
Clinicians 45 9 36 32
Number of forms
given out 758 494 793 852
Number of forms
returned 669 441 619 808
Response rate 88.3% 89.3% 78. 1% 94.8%
Site L C X B
Total
Total number of forms collected 669 441 619 808 2537
N (%) with at least one clinically
important item of information
missing
77
(11.5%)
35
(7.9%)
94
(15.2%)
142
(17.6%)
348
(13.7%)
209
Table 6.4 shows a breakdown of the types of missing records in outpatient encounters. The
most common items not available were:
• Medical notes
• Addressograph labels
• Lab results
• Referrals
• Image results.
Each site had different patterns of types of missing information. For example, there was a
relatively high proportion of missing medical notes in Site B (5.2% of all outpatient
encounters), and Site L compared favourably with the others having only 0.5% missing
medical notes. Site L had the highest proportion of missing image results (4.2%).
Site B had the largest proportion missing labels (3.5%) and Site C had the lowest (0.5%).
For the category of ‘other items missing’ (see Table 6.1), Sites L and C clearly had lower
proportions of missing information than the other two sites.
Across all the sites, the proportion of missing monitoring results was less than one in 100
outpatient encounters.
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Table 6.4: Breakdown of types of missing informatio n in outpatient encounters
Table 6.5 shows that, overall, in nearly a third of the cases where there was missing
information this caused delays for the patient in clinic.
Site L C X B
Total
Did not cause a delay 50
(65.0%)
20
(57.1%)
81
(86.2%)
86
(60.6%)
237
(68.1%)
Did cause a delay
(95% confidence limits)
27
(35.1%)
(19.4, 54.7)
15
(42.9%)
(24.9, 62.9)
13
(13.9%)
(4.6, 35.0)
56
(39.4%)
(21.0, 61.4)
111
(31.9%)
(22.8, 42.6)
Did cause a delay as a
proportion of all patients
(95% confidence limits)
(4.0%)
(2.4, 6.8)
(3.4%)
(1.7, 6.7)
(2.1%)
(1.0, 4.6)
(6.9%)
(3.2, 14.3)
(4.4%)
(3.1, 6.1)
Table 6.5: Whether delays were caused by informatio n being missing
Site L C X B Total
N (%) with at least one clinically
important item of information
missing
77
(11.5%)
35
(7.9%)
94
(15.2%)
142
(17.6%)
348
(13.7%)
N (%) medical notes missing 3
(0.5%)
6
(1.4%)
17
(2.8%)
42
(5.2%)
68
(2.7%)
N (%) with Addressograph labels
missing
18
(2.7%)
2
(0.5%)
13
(2.1%)
28
(3.5%)
61
(2.4%)
N (%) with laboratory results
missing
14
(2.1%)
16
(3.6%)
13
(2.1%)
15
(1.7%)
58
(2.3%)
N (%) with referral letters missing 15
(2.2%)
3
(0.7%)
20
(3.2%)
11
(1.4%)
49
(1.9%)
N (%) with images missing 28
(4.2%)
4
(1.0%)
7
(1.1%)
8
(1.0%)
47
(1.9%)
N (%) with reports missing 9
(1.4%)
4
(0.9%)
6
(1.0%)
12
(1.5%)
31
(1.2%)
N (%) with monitoring results
missing
6
(0.9%)
0
(0.0%)
4
(0.7%)
6
(0.7%)
16
(0.6%)
N (%) with other items missing 6
(0.9%)
2
(0.5%)
28
(4.5%)
36
(4.7%)
72
(2.8%)
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The overall percentage of patient encounters with missing information that caused a delay to
the appointment is 4.4%. From Table 6.6, it can be seen that the median delay was 10
minutes, although the longest time a patient spent waiting was nearly three hours.
If an item of information was missing then doctors had an option to order further
investigations. Table 6.7 shows that this appeared to be done very rarely (overall, only 1.7%
of encounters with missing information).
Table 6.7: Whether further investigations were carr ied out as a result of information
being missing
Table 6.8 shows that overall around one patient in 50 required a repeat consultation to be
arranged specifically as a result of information being missing.
Site Median IQR Maximum minutes delay
L 10 15 45
C 5 8 15
X 10 32.5 90
B 10 10 150
All Trusts combined 10 10 150
Table 6.6: Length of delay for outpatients with cli nically important missing information
Site L C X B Total
Did not require further
investigation
75
(97.4%)
35
(100%)
92
(97.9%)
140
(98.6%)
342
(98.3%)
Did require further
investigation
2
(2.6%)
0
(0.0%)
2
(2.3%)
2
(2.1%)
6
(1.7%)
Did require further
investigation - proportion of
all patients
(0.3%) (0.0%) (0.3%) (0.3%) (0.2%)
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Table 6.8: Whether another consultation had to be a rranged as a result of missing
information
Possible reasons why repeat investigations and repeat consultations were not done as a
result of information being missing included:
• The clinician felt that the clinic appointment could continue safely without the missing
information
• The information was found during the course of the clinic
• A request for further investigations was not marked down by the staff on the data
collection form.
6.4.2 Controlled before-and-after study
Site B implemented some elements of the NHS CRS between the time of baseline (cross-
sectional) data collection and the follow-up data collection. A control Trust (Site X) was
chosen as it had a similar proportion of missing items from the cross-sectional study to that
of Site B (intervention).
Follow-up data collection was undertaken at Site B seven months after baseline data
collection and four months after the implementation had taken place. A second visit was also
undertaken at Site X, six months after the original data collection. At both Trusts, data were
collected from similar outpatient clinics at baseline and follow-up.
Table 6.9 compares the second evaluation with the first and it shows that Site B, after the
implementation of elements of the NHS CRS, showed no overall change in the percentage
of missing items. In contrast, at Site X there was a small reduction in missing items from
15.2% to 11.0%.
Site L C X B
Total
Did not require a repeat consultation 75
(97.4%)
33
(94.3%)
190
(98.5%)
357
(97.8%)
655
(97.7%)
Did require a repeat consultation 2
(2.6%)
2
(5.7%)
3
(1.5%)
8
(2.2)
15
(2.3%)
Did require a repeat consultation –
proportion of all patients (0.3%) (0.5%) (0.3%) (0.3%) (0.3%)
Table 6.9: Response rate and proportions of outpati ent encounters with clinically
important missing information in the controlled bef ore and after study
Table 6.10 provides a comparison of the breakdown of missing items at the baseline and
follow-up data collections in the two Trusts. Following implementation of elements of the
NHS CRS, Site B had an increase in some areas of missing information. In particular, there
was a marked increase in the percentage of missing medical notes from 5.2% to 10.4%,
though there was also an increase in Site X. Site B also had substantial increases in the
percentage of missing addressograph labels and in the percentage with referral letters
missing, while Site X experienced a corresponding decrease (P=0.005 in both cases). There
was little change in some of the other types of information missing but the observed relative
change was worse for Site B for all variables except missing laboratory reports.
Site
B
Time 1
Before
implementation
B
Time 2
After
Implementation
Odds
Ratio
(95%
confidence
interval)
X
Time 1
Control
X
Time 2
Control
Odds
Ratio
(95%
confidence
interval)
Ratio of
ORs
(95%
confidence
intervals)
Total
number of
forms
given out
852 1413
793 1027
Total
number of
data forms
collected
808 1240
619 907
Response
% rate 94.8% 87.8%
78.1% 88.3%
N (%) of at
least one
item of
clinically
important
information
missing
(95% CI)
142
(17.6%)
(12.7%, 23.8%)
223
(18.0%)
(15.0%, 21.2%)
0.99
(0.76, 1.29)
94
(15.2%)
(10.6%,
21.3%)
99
(10.9%)
(8.2%,
14.3%)
1.38
(0.99, 1.91)
0.72
(0.47, 1.10)
214
Table 6.10: Breakdown of types of missing informati on in outpatient encounters in
Sites B and X
6.4.3 Emerging findings from the qualitative analys is
Our initial analysis of the qualitative data has identified a number of factors that might
explain the findings from our quantitative analysis.
Box 6.1 below highlights the factors that appeared to be associated with the variations found
in completeness of clinically important information in hospital outpatient encounters,
Site
Site B, Time 1
Pre-
implementation
(n=808)
Site B, Time 2
Post-
implementation
(n=1240)
Site X
Time 1
Control
(n=619)
Site X
Time 2
Control
(n=907)
Ratio of ORs
(95% CIs)
Number (%) of
outpatient
encounters with
missing
information
142
(17.6%)
223
(18.0%)
94
(15.2%)
99
(11.0%)
0.72
(0.47, 1.10)
N (%) with
medical notes
missing
42
(5.2%)
129
(10.4%)
17
(2.8%)
43
(4.7%)
0.87
(0.43, 1.77)
N (%) with
Addressograph
labels missing
28
(3.5%)
55
(4.4%)
13
(2.1%)
5
(0.5%)
0.18
(0.05, 0.59)
N (%) with referral
letters missing
11
(1.4%)
33
(2.7%)
20
(3.2%)
16
(1.8%)
0.24
(0.09, 0.65)
N (%) with lab
results missing
15
(1.7%)
16
(1.3%)
13
(2.1%)
15
(1.7%)
1.26
(0.42, 3.81)
N (%) with reports
missing
12
(1.5%)
15
(1.2%)
6
(1.0%)
3
(0.3%)
0.42
(0.08, 2.20)
N (%) with images
missing
8
(1.0%)
13
(1.1%)
7
(1.1%)
1
(.1%)
0.10
(0.01, 1.00)
N (%) with
monitoring results
missing
6
(0.7%)
9
(0.7%)
4
(0.7%)
2
(0.2%)
0.33
(0.04, 2.61)
N (%) with other
items missing
36
(4.7%)
31
(2.5%)
28
(4.5%)
12
(1.3%)
0.76
(0.30, 1.92)
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Box 6.1: Factors that appeared to be associated wit h relatively high and relatively low
levels of completeness of information
In terms of the controlled before-and-after study, Site B experienced a number of problems
that may have limited any overall improvements in completeness of information for hospital
outpatient encounters following implementation of elements of the NHS CRS. Table 6.10
shows that there was a doubling in the proportion of missing medical notes between the
baseline and follow-up data collections. Our observations and interviews revealed how
problems associated with NHS CRS implementation put an enormous strain on the site’s
already stretched medical records department and created greater difficulties in finding
medical notes for clinics. One illustration of why this happened was that the new system
frequently created new clinics that did not exist or doubled the numbers of patients that were
supposed to be attending a clinic. Medical records were also collected in advance for these
‘clinics’, only to be returned and re-filed again, once it became clear that no doctors were
available to take the clinic. Patients also needed to be informed of the cancellation to their
appointments and provided with new ones. All this added significantly to the workload for
records staff and limited their ability to obtain complete information for real clinics.
Factors associated with high levels of
completeness of information
Factors associated with low levels of
completeness of information
Electronic case note tracking system used by
the majority of hospital staff.
Paper tracking system for the medical notes,
not adhered to by all staff
Well-resourced medical records library with
potential space for future growth.
Medical records library housed in
accommodation too small to meet the current
and future needs of the service.
Regular renewal of the folders for the notes;
being tougher and stronger than the older
buff covers.
Poor quality, shabby folders for paper notes,
held together by elastic bands – leading to
paper results etc falling out of them.
Preparing the notes for clinic up to seven
days in advance of clinics.
Preparing the notes for clinic two days or
less in advance of clinics.
Frequent and flexible transportation of
medical notes to clinics in other sites.
Lack of a flexible transportation system to
send medical notes to offsite outpatient
departments
Priority that notes are quickly returned to the
medical library.
Medical notes left in wards and offices
awaiting discharge summaries etc.
216
In contrast, Site X happened to make improvements to its paper systems in between the
times of baseline and follow-up data collection. The outpatient staff had set up a system to
coordinate the delivery of referral letters, GP letters and other important clinic information to
a room in outpatients where it was stored in clinic order before being put in the patients’
notes. This may explain the apparent lower levels of missing data at the follow-up data
collection.
6.5 Discussion
6.5.1 Key findings
From the initial cross-sectional survey all sites had a proportion of items missing in their
outpatient departments but this varied across the different Trusts. The main items missing
were the medical notes, labels, laboratory results and referral letters.
The key finding from the controlled before-and-after study was that, in the site that
implemented elements of the NHS CRS, there were no improvements in availability of
clinically important information in outpatient encounters and for some items the change in
availability was significantly worse than in the control area.
6.5.2 Discussion of findings
How sites manage and fund their outpatients departments and their medical records libraries
could be a contributing factor when examining the proportion of clinically important items
missing in outpatient clinics. For example, our observations and interviews revealed that Site
L has an efficient, well-resourced computerised medical records department with an
electronic case note tracking system, which was able to trace all paper medical notes across
the site. It also worked closely with the outpatient departments on the different sites. This did
not prevent some of these items being missing but the numbers of missing notes were
significantly less than at other sites.
In Site B there was no electronic tracking case note system and instead they depended on a
paper system that was not adhered to by all staff. Also, the medical records libraries were
too small for the number of records they housed. The rural area they served provided
challenges as there were five sites up to 50 miles apart and inter-site deliveries took place
only a few times a day.
217
As a result of missing information 1 in 50 patients required a repeat consultation. Whilst
these numbers are not great this would still create frustration both for patients and staff alike
and generate additional demands on a tight Trust budget when several thousand patients
are seen in the outpatients department each year.
We were surprised initially to find that there were problems with missing imaging reports
(particularly in Site L) where a Picture Archiving and Communications System (PACS) was
available. However, our observations and interviews suggest that:
• Many clinicians did not like accessing computers in their clinic and depended on
reports being available in the paper notes or expected the nurses to print them out
• The outpatient staff had access to only a limited number of systems and only a few
had access to PACS.
Our observations and interviews showed that there were significant disruptions following the
implementation of elements of the NHS CRS in Site B, and that these almost certainly had a
major role in preventing any improvement in the availability of clinically important information
in outpatient encounters. Nevertheless, while there was a worsening in availability of medical
records, and some hardware and accessibility problems in the clinics, it was interesting that
those items that showed a slight improvement in availability were often due to the computers
being used rather than the paper results being available. It is possible that this represents a
small improvement resulting from the implementation of the NHS CRS and that there will be
further improvements as the system beds in.
6.5.3 Strengths and limitations of this work
We conducted a large cross-sectional study of four NHS Trusts thus providing up-to-date
information on the prevalence of clinically important missing information in hospital
outpatient clinics. We obtained data on a high proportion (86%) of outpatient encounters,
and were able to produce a breakdown of the different types of clinically important missing
information. Our analysis of observations and interviews (undertaken concurrently with the
quantitative data collection process) enabled us to provide possible explanations for some of
the quantitative findings.
Nevertheless, there were some limitations to our study:
• Although six sites were approached to take part in the study, a wider selection might
have provided a more generalisable sample for the cross-sectional study
218
• The four sites that agreed to take part in the study came from only two of the three
clusters, and there were no sites from London; the small number of sites involved
means that our findings may not be generalisable to the rest of the NHS
• Implementation of elements of the NHS CRS took place in only one site and the lack
of benefits seen may have been unique to that site or related to the collection of
follow-up data soon after the implementation.
6.5.4 Comparison of our findings with those from pr evious studies
As noted above, there have been few previous studies of availability of clinically important
information in hospital outpatient attendances. Our results showed that clinically important
information was missing in a median of 13.7% of outpatient encounters, a similar proportion
to that found in a recent study of NHS surgical outpatients,(166) and in a US study of
primary care attendances.(167) We have not found any published data on the frequency with
which different types of information are missing in hospital outpatient attendances.
6.5.5 Implications of the findings
Having the right information for the right patient in the right clinic is crucial to providing high
quality patient care. This study has shown deficiencies in the availability of clinically
important information in hospital outpatient clinics. While the generalisability of our findings
may be limited, it is likely that clinically important missing information is an important problem
in NHS Trusts across England, and one that could be improved with better systems for
information storage and retrieval.
While we were able to study the potential impact of the implementation of elements of the
NHS CRS in just one site, the findings may be relevant to other Trusts. Wherever possible,
potential implementation problems need to be identified in advance with staff being trained to
deal with these. Also, in order to deal with any unexpected problems it is important to make
sure that extra human resources are available, particularly for medical records departments.
The methods we have used in our study are straightforward and could be used in future
studies. They could also be used for the purposes of audit in Trusts implementing new
information systems that may have an impact on completeness of information available in
hospital outpatient encounters.
219
6.6 Conclusions
The cross-sectional study of four NHS sites showed that at least one piece of clinical
information was missing in around one in seven outpatient encounters; there were apparent
differences in availability of information between Trusts.
The controlled before-and-after study showed no evidence of short-term improvement in the
availability of clinically important information for hospital outpatient encounters in the one site
that implemented elements of the NHS CRS.
220
Chapter 7: Wider contextual considerations and sugg estions for
future deployments
7.1 Introduction
This chapter builds on and broadens the discussion of findings introduced in Chapters 4-6.
Our final work-package (WP6) was originally envisaged as having no substantial empirical
element, rather focusing on integrating the main findings of the research and thereby forming
the summative element of our evaluation. However, as our research progressed, this aspect
of our evaluation has developed to become an empirical WP in its own right. This is because
we had a number of opportunities to gather relevant data relating to the complex contextual
circumstances of deployment of the NHS Care Records Service (NHS CRS) from various
stakeholders that were not directly linked to case study sites. This has, amongst other
things, helped us to gain insights into the various interests of different groups (which need to
be aligned (this does not necessarily mean that stakeholders have to agree) to provide a
workable solution) and an appreciation of how this might best be achieved.(96;168-170)
7.2 Aims and objectives
We aimed to gain an understanding of the wider context surrounding the implementation and
adoption of the NHS CRS and to draw on these to make recommendations for future
deployments.
We sought to:
• Integrate the findings from the previous five WPs with the wider macro context of
deployments
• Identify wider contextual barriers and drivers for diffusion of the NHS CRS and that
have shaped the implementation process
• Relate findings from earlier WPs to the evolving overall objectives of the NHS CRS
and, more generally, to the National Programme for IT (NPfIT)
• Draw conclusions in relation to governance and communications strategies relating
to implementations of this scale and complexity
• Make suggestions for future deployments.
221
7.3 Methods
Data were gathered from a range of complementary sources throughout the evaluation
period. These included formal and informal conversations with key stakeholders from case
study sites (which in part have been covered in Chapter 4), minutes from regular meetings
and discussions with a number of senior personnel in NHS Connecting for Health (NHS
CFH), discussions in our Independent Project Steering Committee and Project Advisory
Board, additional interviews with other stakeholders (e.g. fellow academics, developers,
policy makers, Local Service Providers (LSPs), Strategic Health Authorities (SHAs) and
independent sector representatives) throughout the evaluation period, and researchers’
notes from national and international conferences. We have also studied key wider policy
documents, followed press statements throughout the evaluation period and together with
colleagues on a related NHS Connecting for Health Evaluation Programme (NHS CFHEP)
supported grant, arranged an international conference on the implementation and adoption
of electronic health record (EHR) systems, drawing on experiences from other relevant
stakeholders (please refer to Appendix 21 for details).
The focus of this part of the evaluation was to gain an insight into the various dependencies
between different stakeholder groups and developments, their interests, potential ways
forward, and lessons learned. We analysed data in the light of emerging case study findings
in order to provide a rich contextual picture of the landscape outwith the immediate
environment of implementation (the macro-dimension) that was found to play a more central
part in influencing local implementation than we originally envisaged.(20) The following
sections will explore selected emerging themes in more detail.
7.4 Main findings
A variety of themes emerged from our research. We summarise these in Box 7.1 below and
consider selected examples in more detail below.
Changing political and economic landscape
Uncertainty in relation to future direction
Changes in strategic direction
Parliamentary reviews
Budget savings
Contract re-negotiations
Economic recession
222
Curtailment of some centrally funded NHS CRS functionality
New coalition government
Re-structuring of the NHS
Termination of LSP contracts
Changes to central leadership structures
National leadership versus local ownership
Eroding integrated approach to communication in the organisation
Decline in strategic national leadership
Merger with the Department of Health’s (DH) Informatics Directorate
Perceived “secrecy” in the organisation
Ongoing concerns about security and confidentiality
Concerns relating to security and confidentiality
Access rights of locally stored data and its implications for workflows
Potential security risks of centrally stored data
Media portrayal and impact
Public debate of problems with the Programme and its influence on public attitudes
Potential impact on reputations
Political pressures amplified by the media
Contractual tensions
Contractual re-negotiations over time
Lack of Trusts’ autonomy in decision making in relation to implementation strategy and
software design
Contract focused too much on delivery as opposed to benefits
Tight delivery deadlines
Perceived lack of contact between developers and Trusts
Secrecy surrounding contracts due to commercial interests results in lack of sharing lessons
Seeing a return on investment
National focus on benefits realisation versus “a lack of clarity on where the biggest benefits
of the Lorenzo deployment can be expected”
Long-term future benefits versus immediate benefits
Harder benefits versus softer benefits
223
Suggestions for the future
Realistic standards for interoperability of systems
To what extent should software solutions be built or designed?
Innovate solutions for healthcare delivery problems; use software solutions only if necessary
Showing progress versus incremental approach
Learning lessons from successful international approaches to EHR implementations
Box 7.1: Main themes emerging from our research rel ating to wider contextual issues
7.4.1 The changing political and economic landscape
Since the conception of the Programme – over a decade ago – it has been characterised by
many changes, not only in relation to strategy, but also by changes in central leadership and,
more recently, a reduction in funding in the light of an economic recession.
As a result of the bleak economic climate,(12) centrally funded resources have been
increasingly withdrawn and the more advanced functionalities of centrally procured software
systems have been excluded from contracts in order to save money. These financial
concerns came, as discussed in the opening chapter, on top of the previous problems
relating to contractual negotiations which resulted in two LSPs leaving the Programme early
and contributed to publicly announced plans of the then opposition parties to ‘abandon’ the
Programme.(12)
Following the formation of the new coalition government in May 2010, a new strategic
direction has been mapped out for the NHS. Major re-structuring of the NHS will now take
place, this including the abolishment of SHAs and PCTs, placing the responsibility of
commissioning local services on GPs, and increasing the number of Trusts with Foundation
status.(12)
More specifically, the Programme has been subject to reviews by a variety of governmental,
quasi-governmental and independent bodies.(15;91;171-179) Changes have in the main
centred on the role of NHS CFH, the scaling back of contracts, increased local input in
systems choice, and ongoing concerns surrounding confidentiality and security
arrangements. These will be discussed in more detail in turn.
224
7.4.2 Changes to central leadership structures
Central leadership of the Programme, until recently designated responsibility of NHS CFH,
has over time somewhat lost momentum as NHS CFH has been “subsumed” under the
DH)’s Informatics Directorate. This lack of clear leadership contributed to the uncertainty
about the future of the Programme expressed by many of our interviewees, for example.
“Well I think the jury’s really out on it, the, it’s interesting that the minister who’s now got
responsibility for NHS IT is new to the health field or at least, this is Simon Burns, rather he
was in health earlier in his career but as I understand has had no, you know, involvement for
some years. So to some extent the politicians who are quite vocal in this area such as
Steven O’Brian the Conservative MP he’s now gone off to, he’s a minister in international
development and Norman Lamb who was the Lib Dem health spokesman he’s I believe the
main policy advisor to Nick Clegg so it’s some new faces so what is the new government
going to do, I think we wait to see” (Interview, Independent Sector).
This has been exacerbated by the frequent changes in top-level management in NHS CFH,
which many felt resulted in a lack of coherent strategy and direction “with the left hand not
knowing what the right hand is doing” (Interview, IT Manager, Site H).
The secrecy surrounding the future strategy and difficulty obtaining information in relation to
this not only characterised accounts of stakeholders participating in our project, but also at
times rendered it difficult for us to undertake our evaluation.
Over time, NHS CFH made efforts to increase local leadership whilst at the same time
maintaining overall responsibility for implementation activities. This resulted in somewhat
variable results. The creation of the National Local Ownership Programme (NLOP) (see
Chapter 1) exemplifies this as it was set-up to achieve two seemingly opposing aims,
namely, the sharing of resources locally through central guidance whilst at the same time
empowering local health communities by allowing more input into implementation activities.
Stakeholders tended to question whether these differing aims could in fact be aligned,
expressed through the paradoxical name of “national-local”, which was perceived as an
oxymoron by many.(169) “National” here referred to central leadership, which was still
present although it was to some extent devolved from NHS CFH to local SHAs. However,
individual Trusts still had no input into decision making as they were under the leadership of
the SHAs (so the “local” was not really achieved). As a result, some Trusts that were part of
the NLOP arrangement felt “pushed into” NLOP, believing that they had not enough time to
225
consider implementation options and to make their own decisions as to how their local
projects were managed and by whom.
“Even though we’re now at the local level perhaps it still feels to the acute Trusts like it’s
being pushed at them which I think why, you know, why there is this sort of resistance and a
bit of resentment there, you know, and a bit of, causing a bit of difficulty in actually
progressing” (Interview, IT Manager, Site H).
Nevertheless, the reasoning behind the pooling of resources seemed to be understood as
many argued that expertise in particular needed to be shared locally to benefit from
economies of scale.
Altogether, it seems difficult to find a balance between national leadership and local input as
there are trade-offs in both directions. Focusing on national leadership can help with
achieving economies of scale, but local organisations may lack input in decision making and
are likely to resist. If, on the other hand, one focuses too narrowly on local organisations,
then economies of scale are likely to be compromised. NLOP therefore seems to be a
touchstone of key questions relating to leadership and devolution related issues encountered
throughout the Programme.
7.4.3 Ongoing concerns about security and confident iality
Despite the acknowledgement that there were significant security issues surrounding paper
records, there were ongoing concerns amongst many stakeholders surrounding security and
confidentiality arrangements of the NHS CRS, perhaps reflecting similar issues in other
governmental sectors as a result of large scale information sharing made possible through
Information Technology (IT).(180) There were also concerns expressed surrounding
illegitimate access to nationally or locally held personal data, this being exacerbated by
worries about the difficulties/inability of patients to opt-out of data sharing arrangements. As
one headline reads:(181)
“The implied consent model for the Summary Care Record (SCR) looks set to be scrapped
in favour of a simpler consent model following a recommendation from Connecting for
Health’s advisory group. Implied consent looks likely to be replaced by a model based on
‘consent to view’, providing a simpler more intuitive way for patients to decide who accesses
their record.”
226
Locally, these issues seemed to be the subject of immediate concern, as national
arrangements for storing and sharing detailed clinical data were still in their infancy during
our research. Discussions locally centred on balancing security and confidentiality with the
complex day-to-day service demands and needs of the NHS. On the one hand, security
measures such as Role-Based Access Care (RBAC) (see Chapter 4) arrangements were
viewed as necessary in order to protect confidentiality, whilst on the other hand some of
these arrangements were felt to complicate the implementation and adoption of the NHS
CRS as they could often not be worked out in advance and their impact on organisational
functioning was therefore difficult to predict. These issues therefore often turned out to be far
more complex than originally anticipated. For example, local stakeholders were not clear as
to what information would be accessible by whom and with whose consent. In relation to
RBAC, for example, there were several suggestions on ways to address these issues
emerging from our discussions with NHS CFH and speakers at conferences, which were
somewhat based on opposing assumptions in relation to the number of roles balancing
access rights with protecting confidentiality. Firstly, it was suggested that organisations could
make work group structures as granular as possible, including a hierarchy of access rights.
When mapping individuals to workgroups, they could thus initially be assigned to have
higher levels of access, which could then be amended gradually once the organisation was
confident that workgroup structure was correct. A second approach suggested was to keep
the number of potential roles as low as possible, which of course may compromise
confidentiality and security, but would mean that access to records would be facilitated
resulting in less disruption to the workflow of users.
Nationally, stakeholders tended to be concerned about future arrangements, expressing little
enthusiasm for ‘feeding’ national data systems. Here, the main perceived issues were
surrounding the risk of cyber attacks, national and international misuse of data held on these
records, the general ability of the electronic grid to cope with increasing demands for
electricity resulting from these developments, and the need for appropriate fall-back
measures if systems fail.(182;183)
Tensions surrounding security and confidentiality have to date been particularly apparent
surrounding the Summary Care Record (SCR),(169) but are likely to become of increasing
importance in relation to the NHS CRS as the user-base expands and the EHR becomes
more integrated.
227
7.4.4 Media portrayal and impact
Ongoing concerns relating to security and confidentiality of records are two of the many NHS
CRS related themes that have been frequently and at times passionately discussed and
debated in the media. Many NHS and non-NHS stakeholders felt that the press had
contributed to the negative public perceptions of the Programme/NHS CRS as a whole by
focusing on delays, spiralling costs and various technical and other problems occurring
during implementations.
“I guess the, because a lot of things aren’t in our direct control a lot of the bad press if you
like impacts us quite heavily yet we don’t, it’s not in our gift if you like to do a huge amount
about it, so some of the delays that have, experienced so far” (Interview, Developer).
Developers expressed concern that the negative publicity had impacted on their reputation
(and, in one case, had resulted in a 50% drop in their share prices) and they felt that
influencing the news stories surrounding Lorenzo was somewhat out of their control as they
were often heavily restricted by the LSP.
News coverage of implementing Trusts varied, and it became clear that those whose
progress (or lack of progress) was publicly debated, were under significantly higher public
and political pressure to implement. As a result, LSP resources tended to be pooled at these
Trusts. Indeed, some implementations were played out in the press as exemplar sites, with
their success assumed to either ‘make or break’ the Programme as a whole and associated
software systems, LSPs and developers. As headlines in one paper read:(184;185)
“CSC's future in the £12.7 billion NHS IT Programme is in doubt after it failed to hit a critical
end of March deadline to install Lorenzo Regional Care Release 1.9 at University Hospitals
of Morecambe Bay NHS Trust.”
“A 90-day rescue plan is underway at The Royal Free Hampstead NHS Trust to try and fix a
catalogue of 22 major problems with the Cerner Millennium Care Records System installed
by BT.”
7.4.5 Contracting for health: contractual tensions and new formulae
The relationship between stakeholders involved in implementing and adopting the NHS CRS
was defined by contractual arrangements, which have in turn been shaped by national
arrangements surrounding leadership.
228
Effective contracting between NHS CFH and LSPs is clearly an important pre-requisite to
successfully delivering the NHS’ CRS. However, our research has indicated that the nature
of the contract together with competing perspectives and practical difficulties resulting from
contractual requirements were significant barriers to systems implementation and adoption.
In line with this, some stakeholders argued that such national contracting may in fact be
detrimental to the NHS as a whole as it stifles innovation in relation to software development.
“As a separate stream of development what we found was that the National Programme was
actually stifling our own innovation to quite a considerable extent actually, only because we
had contracted to deliver something which was just enormous, you know, and we had to
deliver it so our ability to do really interesting stuff on the edges was destroyed” (Interview,
Developer).
All stakeholders found the current contractual situation unsatisfactory, despite a general
feeling that over time, relationships between different stakeholders involved in delivering the
software had improved and matured as the different parties increasingly got used to working
together.
First and foremost, there appeared to be a significant disconnect between the requirements
of various stakeholders, most notably between those involved in contracting and those that
experienced the consequences of the contractual arrangements including the SHAs, Trusts
themselves and users of the IT systems. This was perceived to be due to the fact that the
contract left out important functionality (such as social care integration) that was perceived
as crucial to achieve the vision of an integrated solution. It also left out the ability for Trusts
to customise the software according to their needs and influence deployment timelines in
line with organisational readiness.
The fact that the contract was based on the delivery of the technology, and the resulting tight
deadlines, was also viewed as inappropriate and some argued that the contract should in
contrast have been based on delivering early clinical benefits rather than delivery of
extremely ambitious key political milestones. Lack of progress in delivery tended to be
viewed as being due to the overly ambitious implementation timelines specified in the
contract, including unrealistic expectations in relation to benefits and the time needed for
systems to embed. Developers, on the other hand, felt pressurised to deliver and stated that
at the time the contracts were signed there was a lack of negotiation with the supplier which
they felt left them with “no option”, but to sign up to the specified arrangements. Conversely,
229
some stakeholders questioned why the developer had signed up to these arrangements,
which they were clearly not in the position to deliver, resulting in delays in software
development and implementation.
The LSP’s incentive was perceived to be getting the product into the Trusts and some stated
that they “don’t really care about the product itself”. This also meant that LSPs were
perceived to focus on delivery only, and the business change aspects were left to the
organisation. As the contracts were set up between NHS CFH, LSPs and software
developers (see Figure 7.1), NHS organisations themselves, as a main stakeholder in the
contract, felt that the implementation of the NHS CRS was imposed on them as they had no
involvement in decision making in relation to implementation and software. This was further
complicated by the fact that NHS organisations had no insight into what the contracts
contained.
Figure 7.1: A diagrammatic representation of the cu rrent contractual situation
It became clear however that, over time, there was a general move towards more flexibility in
contractual arrangements in order to better meet local requirements. During the Programme,
existing contracts had been revised accordingly, and, as noted above and discussed in
Chapter 1, some contracts had been terminated (e.g. with Fujitsu in the South). In the South,
the reduced contractual obligations of Fujitsu led to a variety of problems, particularly in
Department of Health
Local Service Providers
Developers
SHAs Trusts
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relation to interfacing with existing systems and data migration, which were now the
responsibility of Trusts themselves and which, following the departure of the LSP, Trusts
now had to pay for.
Secondly, some interviewees felt that the software specification in the contract was not “fit
for purpose”, which is why it was thought that iSOFT had made the decision of developing a
new system from scratch as there was no suitable product on the market. The problem was,
however, that this new software did not fit with the specification or timelines set in the
contract. These Output Based Specifications (OBS) were perceived to be far too generic.
Therefore it was necessary to go through a series of “design elaboration activities” after the
contract was signed. As requirements of Trusts had not been “properly baselined” when the
OBS’ were written, this meant costly contract re-negotiations with suppliers when they were
subsequently changed. Some therefore stated that there should have been some initial
flexibility in contractual arrangements as opposed to attempting to define “everything up
front” without having a detailed appreciation of the implementation environment.
Thirdly, there was perceived to be a “complete lack of transparency around those contracts”
(see also Chapter 5). This was problematic for the end-users (i.e. the Trusts), as a result, in
terms of clarity of the scope of the contracts. It was felt that this resulted in uncertainty as to
what software would be delivered to them at what time, which made it very difficult for sites
to prepare for “go-live”.
Developers had their own contracts with service providers and indirectly with NHS CFH,
which they felt impacted on communication and inhibited building relationship with Trusts. It
also made developers less flexible in relation to software development. Nevertheless,
developers felt the LSPs were helping to supply appropriate resources to support the
implementation that they could themselves not provide. There was therefore no direct
contact between developers and Trusts, which meant that developers’ main priority was to
act in line with the contractual arrangements they had with the LSP and NHS CFH, and not
to support local NHS Trusts in ironing out the many difficulties they encountered during the
early stages of implementation.(91;186)
7.4.6 Seeking a return on investment
There were clearly reasons for nationally procuring NHS CRS software solutions, particularly
in relation to cost savings through such large scale contracting and anticipated benefits
associated with inter-operability of standardised systems.(153;187)
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In order to measure progress and incentivise organisations, the implementation of the NHS
CRS has therefore been characterised by a focus on “benefits realisation” and associated
local and national level measurement activities. However, to date the focus here seemed to
be mainly on possible long-term future benefits to the population at large (relating to the
vision) at the expense of any tangible short-term benefits to individual users and
organisations, which was clearly a concern expressed by many interviewees and in
numerous discussions.
Locally, organisations were encouraged to track achieved and potential benefits (or
meaningful use metrics as proxies for benefits these were measurable in the early releases
e.g. data logs of numbers of accesses) from NHS CRS implementation with the help of a
nationally supported Benefits Realisation Framework.(188) However, this was complicated
by the fact that, despite a general recognition of the importance of measuring benefits,
quantifiable benefits are often difficult to measure in the early stages of implementations.
Stakeholders stated that this was particularly true in relation to “cash releasing benefits”,
whilst “softer benefits” were more prominent in the early stages, but these were also more
difficult to measure as they were not quantifiable. However, a range of international
experiences now indicate that, even when investigating benefits in longer-term EHR
implementations, direct net returns on these investments are unlikely to be realised,
particularly not in the short-term.(189) This is likely to be exacerbated in a national context
due to the complexity and scale surrounding the implementation.
Nationally, and as part of the early vision of the NHS CRS, there was awareness of the
potential of making data available for a range of management planning, research and
auditing purposes. The Secondary Uses Service (SUS) was set up to build in such
opportunities for data collection and processing. During the course of our evaluation,
however, this remained more of a vision than a reality as there were only limited clinical data
being captured from NHS CRS systems in secondary care, again due to the limited software
functionality. The DH was however working with suppliers to build the reporting functionality
of applications for existing commissioning data sets. LSPs had a contractual responsibility to
make information available for reporting, but although local reporting arrangements were
progressing, there was no consensus on what data would be collected nationally and how
data from different NHS CRS applications would be consolidated. The political drive for
exploiting such data has however if anything been strengthened following the change in
government.(12) This is potentially important as it is through such re-use of electronic data –
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whether for health planning, public health, audit or research – that there are likely to be
major returns on investment.(189)
7.4.7 Where next? Suggestions from near and far
Generally, stakeholders’ accounts were characterised by uncertainty as to what would
happen to the Programme in the light of the new coalition government and the climate of
economic uncertainty. In the following sections, we consider potential ways forward based
on our findings and ongoing discussions with key stakeholders. Particularly important in this
respect seems to be an increasing focus on standards for interoperability of systems, build
and design considerations surrounding potential software solutions and lessons learnt from
international approaches to EHR implementations.
However, these developments are characterised by the general tension of some who felt
that the Programme needed to show progress, as opposed to others who stated that the
original scope of the deployment was “too ambitious” and that a more incremental
implementation approach would be preferable.
Standards for interoperability
A key problem that needs to be addressed when considering the implementation of national
systems is how interoperability will be achieved. There are broadly two approaches to this.
Firstly, large scale procurement and implementation of national solutions which are
interoperable; and secondly, implementing systems in local health communities or selected
locations that can then be “made interoperable”. At this point it has to be noted that there is
also the possibility of systems interfacing with each other, which is the case with for example
clinical portals. Interfacing means that information can to some degree be accessed from
one system to the other but exchange and updating of information across systems is not as
integrated. Whilst interfacing of systems is technically easier to achieve, the potential
benefits due to a lack of integration are limited.
In relation to interoperability, stakeholders’ opinions seemed to differ. Some felt that
standardising care to a certain extent was necessary and desirable and that this was
achievable only with a national solution, as focusing on local health communities alone
would potentially compromise the benefits that might be achieved. However, others were of
the opinion that connecting up local health economies was exactly where the focus of efforts
should be concentrated as this would bring immediate local benefits, which would in turn
motivate organisations and individual users.
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Others suggested that the national implementation strategy should find a “middle ground”
between these two extremes.(190) This could be achieved by creating a national
procurement catalogue of approved EHR systems by a variety of vendors and setting
standards. Trusts would then be able to choose which software system to implement,
increasing local autonomy, whilst at the same time ensuring interoperability. It was felt that it
would nevertheless be important to keep a common national infrastructure such as the Spine
to connect up Trusts. This would also mean that Trusts could hold a direct contractual
relationship with the supplier. This arrangement was also viewed to be in developers’ best
interests.
Such a middle ground would also allow Trusts to keep existing software systems (which
were often perceived as working very well) instead of having to replace it with national (and
often viewed as less fit-for-purpose) solutions.
The “meaningful use” criteria employed in the US were mentioned in this context as a
potential solution to balance flexibility with standards and with software going through a
central certification process to ensure interoperability of systems that allows for exchange of
data between systems (we elaborate on this further in the section below).(191)
Build and design considerations
In relation to software design, two differing approaches have characterised the
implementation and adoption of the NHS CRS to date: Building software from scratch
(Lorenzo) versus customising existing software systems (Millennium and RiO). It seems
timely to reflect on these differing approaches when considering potential ways forward.
There are benefits and trade-offs in relation to both.
Some of our stakeholders have argued that the initial vision of a truly integrated NHS CRS
could only be achieved with entirely new software architecture as none of the existing
systems were designed to meet the envisaged specifications. In addition, if software is build
from scratch, users can have increased input in software design. However, trade-offs include
a lack of software existence which in turn leads to an inability to plan and envisage the
system working (or even an inability to criticise it as it is still a vision). Other factors include
the length of time that is required to build these systems and the amount of financial
resources that have to be invested, particularly when this is being undertaken on a national
scale. Many stakeholders have therefore questioned why this approach was taken as
opposed to implementing software that exists, and has been shown to work in other
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contexts, but can then be adapted to the specific context of use.(192) The counter-argument
here is that the implementation of existing software may inhibit “true” interoperability” as
these were simply not designed with this specific purpose in mind.
Nevertheless, local implementations of existing systems seem in many ways to be
characterised by similar problems as implementations of software still in development, which
supports the notion that technology is not paramount when implementing software. It is the
interplay between technical and social factors that appears of central importance across
clusters. Here, the way technology is integrated (or adapted to integrate) with local needs is
crucial.
The question that follows is whether it is ever possible for a national solution adequately to
support local needs (and this includes both user and organisational requirements). Here, it is
important to keep in mind that the NHS CRS is implemented in a constantly changing NHS
with changing needs and increasingly heterogeneous groups of staff, specialties and
organisations. It would thus be a challenge to build one system that satisfies all. An
approach based on opening the market to an increasing number of accredited commercial
suppliers and increasing systems choice for local organisations (as is already happening to
some extent) therefore appears to be a sensible way forward. This could help to ensure that
systems satisfy local needs and are used in the most effective way, bringing local benefits in
the short-term as opposed to attempting to begin with the overly ambitious strategy of
delivering large scale national benefits from the start. It is, however, important that such
systems are centrally accredited and fulfil certain standards of interoperability. NHS CFH
could, it was suggested, play a role in facilitating this.
Comparison with approaches to EHR implementation in other countries
Our international conference on EHR implementation and adoption gave us the opportunity
to compare and contrast the approaches being used in England with other parts of the UK
(in particular Scotland and Wales), and also parts of Europe and North America. This
underscored how the various approaches being pursued in these different jurisdictions have
resulted from differences in history, ethos, structure, priorities and scope of health systems;
the challenge of scale was also highlighted, particularly in relation to the inherent difficulties
in extending approaches being followed in the devolved nation to a population the size of
England. It was widely agreed that there is considerable opportunity to share lessons and
experiences, as all are striving to achieve the same ultimate end-points.
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7.5 Conclusions
This chapter has drawn on both the detailed case studies and a wider dataset in order to
provide insights into the wider environment in which the implementation of the NHS CRS has
and is continuing to take place. First and foremost, the Programme has been characterised
by continuous changes in relation to strategy, funding and leadership. This has been
exacerbated by the often publicly debated lack of progress and remaining concerns
surrounding security and confidentiality. The (until recently) top-down implementation
strategy with centrally procured contracts has clearly influenced the way organisations and
users have coped with implementation and adoption as they felt excluded from decision
making, including systems choice. Despite efforts in addressing this issue (e.g. through
initiatives such as NLOP), the fundamental tension of achieving a balance between local
autonomy and implementation of national systems remains. Many have therefore argued for
an opening of the market, which is likely to happen in the future. It is, however, important to
recognise that this may potentially hamper the achievement of national benefits (such as for
example SUS). A certain degree of central leadership is therefore important, and indeed
necessary to coordinate implementation activities and set standards.
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Chapter 8: Conclusion, discussion and recommendatio ns for policy
and research
8.1 Introduction
This report has presented the findings of a longitudinal evaluation of efforts to implement
national electronic health record (EHR) systems – the National Health Service Care Records
Service (NHS CRS) – into NHS secondary care sites across England. In this, the final
chapter, we summarise the main conclusions and draw out key policy and research
recommendations. We also reflect on the strengths and limitations of this work, and begin to
place this work in the context of international efforts in EHR implementation and adoption.
8.2 Summary of main findings: Integration of findin gs across work-packages
Our results indicate that organisations that have begun implementing NHS CRS software
systems as part of the National Programme for Information Technology (NPfIT), have done
so driven by central incentives and multiple visions of better quality and more efficient care,
modernised work practices and strategic benefit for their organisations. Many obstacles
have, however, hampered both local and national progress.
Locally, these have included the relative immaturity of systems (particularly in the North,
Midlands and Eastern (NME) region), a difficulty of the software systems to integrate with
existing work practices and a lack of immediate benefits to users, which in turn often led to
resistance by NHS staff in using systems that were perceived as generating more work
without this translating into improvements in the quality of care, at least in the early stages of
implementation (Chapter 4). These qualitative findings are supported by our quantitative
work, which indicates that in the period of early use the software did not result in a reduction
in the proportion of missing information in hospital outpatient clinics (Chapter 6). Trusts
ability to progress implementation and solve problems was restricted by the complex and
opaque supply chains, and a lack of authority to act or to configure the software. Trusts also
reported disappointment at the lack of clinical functionality, the range of usability issues
encountered, and the consequent views expressed by many staff that the introduction of the
new software systems interfered with rather than supported them in fulfilling their clinical and
administrative roles (Chapter 4). We found that the costs for Trusts implementing the
software, despite the national funding of software systems and some aspects of support,
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were extremely high (Chapter 5). Personnel costs in support of the implementation, in
particular, were much larger than anticipated and had to be compensated for by individual
organisations if they wanted to progress the implementations. The Minimum Data Set (MDS)
that we developed will, we hope, serve as the basis for a robust evaluation tool to help plan
for and assess the costs of future implementations.
Nationally, the strong centrally managed Programme, and its changing management
structures, combined with a high political profile and changing economic climate had
significant consequences for Trusts (Chapter 7). These issues resulted in a sense of lack of
control exemplified by complex contractual arrangements and restrictions in tailoring
software systems according to local needs, both of which have contributed to a lack of local
progress and considerable uncertainty about the future. Nevertheless, the organisations we
studied have in most cases achieved (at least partially) operational systems and at the same
time have developed new competencies in implementing complex IT systems as they have
over time done their best to make the new systems fulfil both user and organisational
demands.
8.3 Strengths and limitations of this work
8.3.1 Strengths
The scale and real time nature of this evaluation of EHR implementation in English
secondary and community healthcare settings makes it unique.(4) The strengths of this work
include the mixed methods design and contemporaneous multi-faceted longitudinal data
capture.(193) This study has also been theoretically grounded, drawing on economic
analysis, sociotechnical models of change and organisational learning. The result is that this
evaluation has allowed a rich, multi-faceted nuanced appreciation of the implementation and
adoption of the NHS CRS. Its theoretically informed research design, data generation and
analysis will we hope allow transferability of findings and methods beyond the immediate
context of this evaluation.(50;194)
The demonstrated ability of a skilled, experienced, multi-disciplinary research team is also
one of the strengths of this research. This team has shown a willingness and ability to
reconsider and, where necessary, revise our research approach in the light of changing
realities on the ground (Chapter 2). New insights were made possible by the combined
involvement of researchers with different methodological backgrounds, skills and
experiences. During the conduct of the research we have developed a cadre of researchers
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who have been involved in a highly complex evaluation and who as a consequence have
emerged with a range of relevant skills and insights appropriate to the study of future health
IT implementation efforts.
We used purposive sampling to ensure coverage of the main NHS CRS software systems,
and an appropriate mix of secondary care Trusts. This strengthens the credibility and
transferability of our findings. The sample includes a range of Trusts, of small and large
dimensions, with Foundation and non-Foundation status, teaching and non-teaching, in
acute care and mental health, across large geographical distances and in urban centres and
representing a range of different implementation strategies. Unsurprisingly, as a result we
have a number of different experiences of NHS CRS to report. This diversity of context and
data are we believe a strength, particularly in the area of study of EHR where much reported
research relates to a single site, often a well resourced centre of excellence.(19)
Very substantial volumes of data were generated and obtained from a variety of sources
covering a range of stakeholder perspectives. In attempting to cover the national context
whilst still retaining the importance of local contexts, we have drawn on a case study
approach. After initial detailed analyses of individual case studies, we then analysed findings
across contexts allowing for wider transferable lessons to be drawn. Case study findings as
well as wider themes were discussed at length within the research team in data analysis
workshops, to check understanding, confirm findings, refine ideas and expand propositions.
Throughout the study, these emerging findings were fed back into subsequent fieldwork and
analysis. In relation to the main findings and given the timelines we had to adhere to, we
believe that we have reached saturation in relation to early implementation considerations,
though we are sure that over longer timescales many new issues will emerge as NHS CRS
software is (to degrees) adopted into everyday use, extended to more clinical realms, and
the data collected therein are exploited in new ways.
A further strength of this study was our ability to provide formative feedback to NHS
Connecting for Health (NHS CFH) and to the Trusts we were working with. In most cases the
Trusts were very appreciative of our work, interested in our findings and fully able to respond
to the analysis we gave them even when it was not directly in line with their own views.
Areas of particular interest included emerging concerns amongst staff on the ground and
potential early barriers to successful local and national implementations. Indeed, the
potential for formative work within such evaluations, and the benefits that can accrue from
such an approach, are counted as one of the positive outcomes of this work.
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8.3.2 Limitations
First and foremost, our sample may not be representative of the full set of ‘early adopters’ or
the wider population of NHS Trusts, the majority of which have not so far participated in NHS
CRS implementations. The experiences of the Trusts participating in our research may also
not be representative of those Trusts who might join the Programme later, because of
lessons that are learned from research such as this. For example, the Trusts we studied
incurred some costs and spent time in a trial-and-error process that may not need to be
repeated. Equally, ‘early adopter’ Trusts were often the beneficiaries of substantial financial
support (Chapter 5) that is unlikely to continue to be available, thereby affecting the true
nature of any opportunity costs faced. We have identified, where appropriate, instances in
which economic principles and our evidence suggest that ‘early adopters’ experiences may
not reflect the likely experience of the remaining Trusts in England.
Our sample has been affected by a number of concerns in the research environment. A key
issue has been gate-keeper influence at all levels. This has resulted in restricted access to
some stakeholders, including patients and healthcare professionals, often carefully and
appropriately “guarded” by Service Leads and IT Managers, and in some instances to Trusts
themselves. This may also have been because Trusts were aware of the limited clinical
functionality that had thus far been deployed. Furthermore, for Trusts engaged in
implementing the NHS CRS and under great pressure and politically charged deadlines,
participating in the evaluation was of relatively low priority. Hence limited time and resources
were made available to our research. The nature and depth of data collected at different
case study sites thus varied. We also faced a general lack of access to groups such as
developers and government stakeholders, again, because of the at times politically charged
nature of the NHS CRS and prioritisation of resources.
This research environment meant that some stakeholders seemed to hesitate in speaking
openly, particularly in relation to what they considered to be sensitive commercial
information including costs and contracts. We addressed this by encouraging participants to
speak ‘off the record’ (i.e. not recorded and not attributable). For the same reasons, we had
difficulty obtaining documentary evidence such as contracts, business cases and minutes
from higher-level meetings. One important piece of information that was challenging, if not
impossible, to obtain related to the ’go-live‘ dates of Trusts. This had a significant impact on
our sampling strategy and led us in some instances to sample Trusts that did not actually
eventually go-live during our evaluation, despite original plans. Our picture is therefore
necessarily incomplete, which was further exacerbated by the need to focus on a limited set
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of analytical techniques due to practical constraints. Nevertheless, we hope that our dataset
will, in the future provide ample opportunity for secondary analyses.
Not only is our picture incomplete, but it is affected by our own intervention in the field. Our
formative feedback strategy (see strengths above) may have influenced the information they
provided back to us as research participants. They might also have changed their local
implementation efforts, for instance to address local issues identified by the research team in
ways that they would not otherwise have done.(25)
We also recognise that, with respect to the general field of EHR implementations, the
transferability of our conclusions may also be limited by the restricted number of software
systems within the NHS CRS, which we have focused on. This may become increasingly
important if, as expected, the market becomes more open in the future.
To conclude, despite the clear advantages of a large, multi-site evaluation undertaken by a
multi-disciplinary team, there are also some important potential limitations arising from this
work. First, the volume and range of data and number of researchers collecting these,
rendered it challenging at times to keep an overview and to pull findings together. Our
diverse backgrounds and experiences meant that data collection techniques and
assumptions varied. We must also acknowledge that the qualitative findings and the way
they are presented constitute accounts of who we are, reflecting our world-views,
interpretations, academic backgrounds and previous experiences. Their content draws upon
interpretations and translations of participants’ viewpoints rather than “raw” data that “speak
for themselves”.(57;195) They are thus contingent, constructed or “partial truths”, though no
less credible for that.(62;195)
Our request for additional funding would have allowed continuation of our research into a
longer period of implementation and adoption, but this was unfortunately unsuccessful; our
findings thus emerge from relatively short periods in the field (i.e. covering up to 18 months
of NHS CRS systems use). This obviously results in lack of insight into longer-term
consequences, which may be particularly important in order to allow anticipated and
unanticipated consequences to emerge.(189) We thus have an important story to relate, but
one that is, unfortunately, only partially complete.
8.4 Relating this work to the broader literature
We have reported on the most substantive and sustained prospective evaluation of the
implementation of EHRs ever undertaken and have found evidence of persisting difficulties
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being encountered on the ground as a result of nationally procured systems implementation.
Most IT implementations in healthcare settings lack robust and sufficiently theoretically
informed, mixed methods evaluation as many commentators have previously
argued.(110;196-198)
Broadly, our results confirm findings from other evaluations of the introduction of EHRs into
healthcare settings, be it primary or secondary care.(199-202) This is particularly true in
relation to repeatedly identified facilitators and barriers to successful implementations in the
complex healthcare setting including technical, social, and organisational factors, as well as
the complex interrelationships or “fit” between these.(203-207)
However, our findings have also provided a deeper insight into the complexities surrounding
the national implementation of EHRs. Local deployments in NHS sites were heavily
influenced by wider contextual factors, the impact of which intensified over the period of our
evaluation. In addition, we have developed a more fine-grained understanding of how
implementing national electronic health record systems has major impacts locally, not only
on organisational functioning, but also workflows of individuals, locally incurred costs and
proxy measures of patient safety.
Some of our findings can be applied to other settings such as primary care, particularly in
relation to macro-environmental influences. Others, on the other hand, reflect the complex
and disintegrated nature of the secondary care environment, where many different staff
groups work-out the technology in more complex ways than in other settings.
8.5 Relating this work to broader IT and policy dev elopments
Our research has indicated that despite major concerns with the details of the
implementation, there remained widespread buy-in into the central vision of the Programme
and EHRs and, more generally towards moving healthcare services from a paper-based into
a digital-record based era. There is, however, considerable uncertainty in relation to the
future strategic direction of the implementation of the NHS CRS in secondary care settings
(Chapter 7). Plans have been announced, but the implications for the future IT strategy and
implications for NHS CRS deployments in particular are, at the time of writing, uncertain.
The plans that have been announced are likely to encourage competition from different
software systems suppliers and confirm the move away from an entirely top-down nationally-
led implementation approach. Whilst this approach may also allow early local benefits to be
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realised, it is also likely to bring a new set of challenges, particularly in relation to standards
for systems interoperability. It should also enable more local input in implementation
activities and system choice, which in turn could facilitate local problem solving and
engagement.(186) This is in many ways the approach that was planned before the
Programme was conceived. Back then many parties argued that there was a greater need
for integration and interoperability to bring the desired large scale benefits. But there was a
general feeling that if funding to deploy systems would be devolved to Trusts, this would not
necessarily result in sufficient IT investment be made.(208) Therefore, it was felt that a
central solution would be more appropriate. Both of these issues remain of concern in
relation to any future strategy.
At present, the general strategic direction seems to have moved somewhere between the
two, with some local input and choice, but still to some extent guided nationally.(209) This
more devolved strategy would encourage capacity building at local level – a strategy aligned
with the more general policy of devolving responsibilities and power in the NHS, made
evident, for example, through the increasing number of Trusts obtaining Foundation status
(currently 129 out of 251).(210) These Trusts have considerable autonomy and are
accountable directly to the Department of Health (DH). An increasing number of these
Foundation Trusts have, over the period of our evaluation, decided to implement systems
outside the Programme.(211) Thus, Foundation Trust status in combination with a national
implementation strategy is counter-intuitive. It means that Trusts are on the one hand
encouraged to be independent, whilst on the other hand, restricted to use nationally
procured systems. In addition, the new strategic approach has to date been largely untested
and will need careful planning and flexibility to suit the evolving needs of the NHS.
It is therefore important to recognise that the implementation of the NHS CRS is in itself
situated within the larger and constantly evolving structures of the NHS, the DH and the
government. The IT strategy has significant implications not only on the way care is been
delivered, but also on whether and how its outcomes are aligned with those intended with
other existing strategies. Our research indicates that it is the combination of change reforms
supported by IT strategies that can maximise the chances of successfully implementing new
systems. Two disjoined reform strategies would have undesired consequences with
stakeholders finding it difficult to prioritise and creating a feeling of lack of direction. Similarly,
our research findings indicate that some of the core patient-centred reforms envisaged for
the NHS are only likely to be achieved on the back of successful implementation and
adoption of interoperable NHS IT systems.(12)
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What is needed is a clear description of this wider strategic approach (i.e. IT strategy aligned
with other NHS policy reforms), with detailed plans and specific incentives for systems
integration, standards etc., which are agreed and defined in consultation with NHS
stakeholders and the public. Policies are bounded by existing infrastructures. Aligning the
interests of such a disparate group of stakeholders is likely to prove particularly challenging
in large, increasingly fragmented and competitive health systems of the kind that is now
found in England.(170) In the case of NHS IT, the National Programme, and NHS CRS
implementations contributed to the building of a yet to be finalised national infrastructure
(e.g. N3 and the Spine), with contracts with suppliers coming to an end in 2015.(212) There
seems to be a decision to be made as to its continuation or termination. But the choice is
conditioned on an interplay between future policy and existing infrastructure, with the one
being both a means and an outcome of the other.
8.6 Lessons learned and implications
In our evaluation of the NHS CRS, we found some success stories as well as several
problematic situations, complexities and lessons to be learned. These lead to implications for
policy. However, it has to be noted that our evaluation of the NHS CRS is not an evaluation
of the entire NPfIT. Many success stories of the NPfIT can be accounted, such as the
implementation and adoption of Picture Archiving and Communication Systems (PACS,
which brought immediate perceived benefits), NHS Mail, and the building of both national
(Spine, N3) and local infrastructures as well as the development of standards (e.g. the
interoperability toolkit).(213) In addition, the Programme has helped to develop health
informatics expertise within the NHS (although there is still a need to build on this).
Policy makers have already started to shift the focus to more local efforts to procure and
implement electronic health records, these being driven by the changes in outlook of the
coalition government, the planned changes to the NHS in England and also reflecting the
current economic climate.(12;16) In the light of this evolving policy landscape, and drawing
on our research and broader international experiences, we have a range of
recommendations, which we have summarised in Box 8.1.
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• There will always be a need for flexibility and an ability to respond to evolving
needs.
• Concurrent policy initiatives need to support electronic health records
implementation.
• There is a need to focus on getting NHS CRS systems working in sites where
implementation has begun. On a related note, funding needs to be continued for
sites that have already committed to implement NHS CRS.
• Careful consideration needs to be given to intellectual property rights in relation to
future developments – the NHS as a whole should benefit from systems developed
by them (e.g. Lorenzo).
• A governance structure is needed to develop standards, set quality benchmarks,
create incentives, liaise with suppliers, and develop expertise. This structure
should facilitate local engagement in key decisions.
• There is a need for more local ownership – systems should be implemented out of
a perceived need, whilst complying to centrally determined standards for
interoperability.
• We now need to move away from technology driven models of implementation
towards a recognition that technology is an enabler of improved organisational and
care processes.
• There is a need for a more transparent commercial architecture which encourages
the emergence of a larger range of software systems and service providers
working through smaller contracts. This landscape should be centrally regulated
and incentivised.
Box 8.1: Summary of key policy recommendations emer ging from our work
8.6.1 Policy implications for the English NHS
In the short-term, the sites in which NHS CRS implementation has already begun should be
supported in their choice to maintain their system if they wish, or to change to other software
systems, not necessarily in line with the historic NPfIT strategy. Funding for this stream of
the Programme needs to be continued for the sake of the Trusts committed to the NHS CRS
software systems. This support may need to be over extended periods of time and should
have realistic timescales. Efforts should furthermore focus on the implementation of clinical
software modules (such as ePrescribing), so that there is an opportunity to establish whether
245
these do in fact once used translate into the desired improvements in the quality and safety
of care.
Funding is also needed to retain, and build on the very substantial and hard won knowledge
and skills already developed in individual sites and across the NHS. The considerable work
by Trusts and NHS CFH in informing the design of the Lorenzo NHS CRS system should be
seen as, at least in part, the intellectual property of the NHS, which the NHS as a whole
should benefit from. This work should not be lost; it will require careful consideration of
intellectual property rights in relation to any future developments (e.g. international markets).
In the longer term, it is important that some ‘top-down’ responsibilities are retained in order
to ensure that electronic health records are implemented in an integrated way. We
recommend a hybrid governance structure that will encompass the input of both an NHS
wide, public, accountable central authority as well as considerable local involvement in
decision-making and implementation strategies. Building on other international models, we
envisage the role for one or more NHS-wide bodies (such as NHS CFH, the DH’s
Informatics Directorate or the newly established NHS Commissioning Board) to include
coordinating and facilitating development of common and open technical standards
(including support for some aspects of software certification), setting quality benchmarks
which Trusts can use (e.g. for usability and safety), creating incentives for inter- and intra-
organisational learning, liaising with supplier communities, and developing expertise and
drawing together specialists. The exact role of this governance structure will need to be
negotiated.
Independently from the setting-up of central or NHS-wide bodies, it is essential that
implementation activities are locally owned and driven. In particular, organisations should not
be encouraged to replace existing systems that are working for them; development of EHRs
should rather stem from perceived needs and a well articulated and understood case for
change within the local health economy. Locally driven implementations should align with
nationally set standards to achieve, in the longer-term, a joined up healthcare delivery model
and the overall vision underpinning the NHS CRS. We recognise however that this balance
is likely to prove extremely challenging to achieve, as there are some major trade-offs which
need to be considered. These include, above all, the risk of potentially conflicting local
priorities resulting in insufficient drive and funding for such developments, problems with
systems interoperability, and entrenchment of local work practices rather than the
'transformation' of healthcare nationally.
246
A consequence of this should be a move away from technology-driven models of
‘implementation’ (e.g. the focusing on putting computers on desks, trolleys or even into the
hands of clinicians) and reflect increased attention to Trusts operational needs and business
priorities, their work practices, and potential for beneficial change in work process. The
findings from this evaluation suggest the need to refocus attention around ‘adoption’.
Adoption should not be seen as a discreet period of change driven by the arrival of a new
technical system, but as an on-going and most likely lengthy collective ‘working-out’ in which
technology is seen and used as an enabler of improved care and decision-making
processes, rather than an end in itself. As adoption, change progresses and requirements
for systems’ functionalities are also expected to change. Contracts with system suppliers in
general should not assume a linear implementation model, but a flexible one that can be
amended suit to emerging demands.
There is also an opportunity to work to align the strategies of the NHS and a wider variety of
commercial software suppliers and service providers. A stronger and more transparent
commercial architecture could be of great benefit to all parties, but must not repeat the
customer–supplier disjunction of the NPfIT. We expect to see such a market emerge with a
larger range of software systems and service providers and working through smaller
contracts. This would require providers to demonstrate compliance with agreed
interoperability standards that have been built ‘bottom-up’, but have achieved a minimum
level (benchmark) of usability, clinical safety and validity as well as service quality measures
in relation to pragmatic clinical practices and business processes.
8.6.2 Implications for the international community
Our experiences of studying the English experience offers a number of potentially
transferable lessons for ongoing international efforts to implement electronic health records.
First and foremost, there remain important drivers for the long-term the implementation of
integrated EHRs, these including in particular the potential for increased accessibility, which
is important considering the major advantages associated with digitised data in relation to
facilitating audit and research. However, the procurement of national systems in England
had several consequences for organisations and individual users. Procurement reflecting the
centralisation of the process was undertaken to save costs and ensure an integrated
approach, but this meant that implementation timelines were being driven according to
political timeframes in line with the procurement arrangements. We therefore advocate that
the basis on which these systems are chosen should lie in assessing their potential for
improving clinical care processes. Procurement decisions should not be based primarily on
247
unrealistic assumptions of achieving cost-savings or even returns on investment, but rather
on introducing clinical functionality early so that these systems are used. In other words, the
value these systems add should be based on clinical and not financial or political arguments
as measurable benefits will take a long time to materialise.
The English experience has also illustrated that the primary initial concern of national
strategies should not be systems integration, but instead focus on ensuring that systems are
used locally and bring some benefits to organisations and users before they are connected
on a larger scale. In this context, building national systems from scratch is unlikely to result
in success as the focus on systems interoperability and standardisation means that local
customisation is compromised from the start by procuring a “one-size-fits-all” system. This
will need to be coupled with a realisation that the main benefits of these systems are likely to
accrue in the longer term, from both local re-invention and secondary uses of data for
management and research purposes.(189) That said, there is, as noted above, an important
need to agree and enforce standards for interoperability.
Strategically, it is further important that any health informatics policy is integrated with
concurrent policy initiatives and reflects the dynamic environment in which it is taking place.
In England, this has to some extent be achieved (e.g. by gradual movement towards a more
localised approach), whilst on the other hand it was (and still is) hard to adapt nationally set
arrangements to evolving needs (e.g. contracts with Local Service Providers (LSPs)). The
consequences of these are often still hard-felt on the ground. Admittedly, it is difficult to
achieve this balance as the NHS is itself continually changing. It is, for instance, becoming
increasingly prone to becoming ‘privatised’, which is in itself at odds with any nationwide
transformation of the service, ‘top down’ or otherwise.
Conversely, it is also important to balance changes in strategic direction with keeping a
central tenant of working towards a coherent vision without changing this to an extent that
leaves stakeholders confused and uncertain about the future.(12) For example, although the
overall “vision” of an “information revolution” discussed in the government’s White Paper,
Equity and Excellence: Liberating the NHS, is to an extent predicated on people having: “…
an accurate record of their care, available to them electronically” there is no formal mention
of the NPfIT or indeed the NHS CRS suggesting that the focus of attention has shifted and
that these very substantive initiatives may in key circles be viewed as history by the coalition
government.(12) In addition to the shifting nature of aims over time, it is also apparent that
these did never match the vision of seamless integration with the actual implementation
strategy. There is thus a need to reflect on the national approach to implementing EHR
248
systems. On one hand, systems were nationally procured to ensure interoperability, but on
the other hand, they were not conceived as a single national solution as a range of different
suppliers was involved. The degree of integration and interoperability across systems,
although open to speculation, may therefore never have been realised even if the national
implementation would have proceeded according to plan.
8.7 Implications for future research
There are a range of implications for future research that can be drawn from our
experiences. Most importantly, there is, we believe, still a need for more independent
longitudinal evaluations of IT initiatives, following implementation efforts over substantially
longer periods of time. Such studies allow insights into the way technologies become
embedded (or not) and are made to work in and across organisations.(169;207;214;215)
Similarly, detailed studies of Trusts (and sites in other countries) where EHR systems have
become established and are in every-day use could inform future policy and delivery
methods, and the ways in which it may be possible to maximise the realisation of benefits
and returns on investment. This will require funding bodies to allocate the required
resources.
Future studies should also examine the transformative power of EHR in changing (or not)
clinical practices and healthcare professional roles and in conditioning new forms of
patienthood and a re-conceptualisation of healthcare delivery models and healthcare as
such.
Research is similarly needed into the often neglected processes of transition from paper to
electronic records, or between one generation of electronic systems and another. As in this
study, this turns attention to the extended processes of change (changing) and the ways in
which the active users of new systems work-out how to appropriate the various affordances
of any given technology into their work practices and processes of patient care.
A focus on cross-country international research in relation to technology innovation and
implementation and adoption processes and overall visions, could help inform future UK
developments. In particular, the understanding of international experiences could inform the
complex choices and trade-offs faced in EHR implementations between, for instance:
security and confidentiality; interoperability and localisation; and standardisation and
customisation.
249
There is furthermore currently a lack of attention surrounding the ways in which large-scale
electronic data systems in the health service can be managed and maintained in the long-
term (including disposal and security arrangements). This will require considering the whole
lifecycle of electronic information.
Issues that future research will also need to resolve are related to the ethical and legal
concerns surrounding research into EHRs, particularly into the potential implications when
evaluating commercial products (libel). This has, for example, been a cause of concern for
our research team, which has led us to seek expert legal advice in this respect.
Introducing technologies into healthcare environments clearly requires relationship building
between suppliers, patients and carers, clinical and administrative users, professional bodies
and healthcare providers. This has so far received limited attention and is also likely to help
addressing issues surrounding clinical engagement. Research can help to guide these
multiple interests towards a productive dialogue. There may also be a need to learn from
other industries where this has been realised.
Overall, we would argue that EHR-based innovation in healthcare should not be conceived
of as essentially technically driven (i.e. founded on the inherent properties of in EHRs or any
other technology), but should be characterised by new ways of working that appropriate
technologies and seek new ways of delivering better care. Detailed work process mapping
and user centred design, combined with exploring options for innovation in the way care is
delivered, should be central to future investigations. Fundamental to this view is the
understanding that automation without redesigning services will just magnify existing
problems.
8.8 Conclusions
The initially anticipated “full integration” of NHS CRS software systems by December 2010 is
still far from being realised. While RiO has achieved a relatively wide installed base, there
have in contrast been very few implementations of Lorenzo software and those of Millennium
are still behind the original schedule. The implementations in acute settings (Lorenzo and
Millennium) have not only been on a smaller scale than originally planned, but also with
more limited functionality. Rich clinical functionalities have so far not been implemented.
Yet, the NPfIT – and especially the NHS CRS – remain as visionary IT endeavours that may
long be remembered in the history of health policy and health informatics. Although our work
250
has clearly shown that many users, managers, service providers and implementers have
been sorely bruised by the initial experiences of attempting to implement a comprehensive
national EHR system, history may – particularly if we at this important juncture now make the
right calls – be more forgiving.
251
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Contributorship
Dr Maryam Ali (MA) joined the evaluation team in April 2009. She was responsible for
coordinating meetings for the London team and also for helping to initiate research in the
Southern cluster, both in relation to the collection of data and also learning about its history
from secondary sources. She also helped with establishing contacts with case study sites in
the South. MA contributed to data analysis and interpretation, participated in meetings and
workshops, and helped with drafts of publications as well as the preparation of reports. She
contributed to the institutional section of this report.
Professor Anthony Avery (AA) contributed to the writing of the original bid, particularly Work
Package (WP) 5. He led the Nottingham team during the study and had overall responsibility
for successful completion of WP4, and the WP5 study on examining completeness of
information in hospital out-patient clinics. He was a member of the Project Management
Group and contributed to the team meetings and commented on drafts of the report.
Professor Nicholas Barber (NB) contributed to design of the funding application and
subsequent project; design of individual studies, interviewing, analysis and authorship.
Dr Tony Cornford (TC) contributed to the writing of the original bid, particularly WPs 1-3. He
led the London School of Economics team during the study and had overall responsibility for
successful completion of WPs 1-3. The theoretical dimension of this project is based on his
work on information systems. He contributed to the design of individual case studies,
participated in data collection, and led the analysis across case study sites. For the report,
he coordinated the writing and was the author of sections of Chapter 4, executive summary
and Chapter 8. He contributed to overall analysis and policy implications, reviewing and
commenting on drafts of the report. He was a member of the Project Management Group.
Kathrin Cresswell (KC) was involved in writing the grant proposal and setting up the project.
She was grant-holder as well as Project Co-ordinator and therefore involved in every aspect
of the study. She led on writing the final report and was also lead researcher on three case
studies and overall lead researcher in the North Midlands and Eastern cluster.
272
Dr Sarah Crowe (SC) assisted with the recruitment of hospital sites, and was responsible for
WP4 contributing to all aspects of data collection, analysis, and interpretation. She also
collected data for WP6 and contributed to the overall synthesis of key findings across sites.
Dr Bernard Fernando (BF) was a grant-holder on this project and contributed to Steering
Group meetings.
Professor Ann Jacklin (AJ) was a grant-holder on this project and contributed to Steering
Group meetings.
Dr Yogini Jani (YJ) evaluated the pilot of RiO ePrescribing at Site M, developed and piloted
tools for medication reconciliation and missing information in medical records, reviewed and
commented on the final report; contributed to the writing of Chapter 6; commented on and
piloted the CLICS survey, and contributed to writing, reviewed and commented on the case
study for Site M.
Dr Ela Klecun (EK) contributed to writing the grant proposal and was one of the grant-
holders. She contributed to data analysis cross-sites and overall policy implications. She
wrote a number of sections in Chapter 4 and reviewed other sections. She designed the
survey tool CLICS (with TC and VL), and distributed it in Site D (with VL).
Dr Valentina Lichtner (VL) participated in recruitment of sites; carried out data collection in
Site N, O and P, and with interviews of different stakeholders in relation to integrated clinical
pathways; designed the survey tool CLICS (with TC and EK), pilot it (with YJ) and distributed
it in Site D (with EK); contributed to data analysis cross-sites and overall policy implications;
was responsible for writing sections of Chapter 4 and contributed to the writing of the
Executive Summary and Chapter 8, as well as reviewing and commenting on all sections;
she was the author of Case Study P, and contributed to the case study of the South. The
drawing on the cover is hers.
Kate Marsden (KM) was the lead researcher on WP5. She wrote the first draft of Chapter 6
and contributed to the case studies in Sites B and X; she also reviewed and commented on
the final report.
Zoe Morrison (ZM) was a researcher on this project and contributed to data collection and
the writing up of the case study for Site X.
273
Dr James Paton (JP) was a grant-holder on this evaluation and a member of the project’s
Steering Group.
Dr Dimitra Petrakaki (DP) participated in the recruitment of three sites in the South (R, F and
a site that ultimately did not participate); carried out data collection for WPs 1-3 in Sites C, R,
F and BB, conducted all interviews with patients in Sites B and H; helped in data collection in
Site B; contributed to data analysis cross-sites and overall policy implications. She was
responsible for writing a number of sections of Chapter 4; contributed to the writing of
executive summary and Chapter 8 and contributed to Chapter 3. She was the author of the
case studies of Sites C and R, the case of patients and she contributed to the case study of
the South.
Professor Robin Prescott (RP) was a grant-holder on this project and a member of the
Steering Group. He advised on all statistical considerations and undertook the statistical
analysis for WP5. He was also involved in report writing.
Dr Casey Quinn (CQ) was a grant-holder on this evaluation and a member of the Steering
Group, with particular responsibility for the health economics aspects of the project. He
contributed to data collection, analysis and the writing of Chapter 5.
Dr Ann Robertson (AR) contributed to the management of the project, to recruiting
participating sites and individuals and to all aspects of the evaluation's data collection,
analysis and dissemination, including being the lead researcher for two of the reported case
studies.
Professor Aziz Sheikh (AS) was the Principal Investigator for this evaluation. He conceived
the idea for this evaluation, led the writing of the grant proposal, chaired the Project
Management Group, Steering Group and Project Advisory Board, and convened the
Independent Project Steering Committee. He oversaw all aspects of data collection, analysis
and interpretation, and writing up of this report and study publications. He is the study’s
guarantor.
Dr Amirhossein Takian (AT) participated in the recruitment of four sites in London and one
site in the South. He was the lead researcher in Sites D, E and M in the London cluster;
carried out data collection, analysis and interpretation for WPs 1-3; facilitated WP4 in Sites
D, E and M (carried out by SC and CQ) as well as CLICS at Site D (carried out by VL and
EK); contributed to data analysis cross-sites and overall policy implications; was the lead
274
researcher for WP5 until June 2009; developed and piloted tools for medication
reconciliation and missing information in medical records in Site A and another NHS setting
(with NB,YJ and TA), he was the lead author of Chapter 3; contributed to Chapter 4, as well
as reviewed and commented on all sections. He was the author of the case studies of Sites
D, E and M.
Dr Katerina Voutsina (KV) collected data from secondary sources to provide a historical
account and a comprehensive report of the special contingencies which have met in the
process of implementation and adoption of the NHS Care Records Service (NHS CRS) in
the Southern cluster. She contributed to the story and the case study of the South. She also
reviewed and commented on the final report.
Dr Justin Waring (JW) was a grant-holder on this evaluation.
275
Glossary
Access control A system that allows to control access to
data held on a particular computer system
Acute Trust A Trust that provides secondary care
services
Adoption The process of starting to use a new
technology either on an individual or a group
level
Accident and Emergency (A&E)
Part of the hospital that provides initial care
for patients with acute problems.
Architecture ¹ The selection, design, and interconnection of
the hardware of a computer system
Approval to Proceed (ATP) The formal approval to begin the go-live in
the ‘early adopter’ phase.
Audit trail Chronological recording of organisational
activities often used for review of
organisational performance
Authenticated ¹ The confirmation following user
authentification that the end user is actually
the person he/she purports to be
Bandwidth ¹ An industry standard term to measure the
amount of data you can send through a
network or modem connection. The more
bandwidth, the more information that can be
transferred at one time
Benefits realisation The process of achieving benefits of a
particular project as detailed in the business
case
‘Big-bang’ implementation The whole organisation moves to a new
system at the same time
Broadband ¹ A telecommunications medium composed of
a bandwidth high enough to transmit high
quality voice transmissions and a wide band
276
of frequency. Television, microwave, and
satellite transmission are all example of this
medium. This is used mainly in relation to
Internet access
Business case
A document outlining the reasons for
initiating a particular project in an
organisation
Business change
Initiating organisational change that affects
the way the business operates
Business as usual
A state the organisation achieves after
implementing change that is characterised by
enabling the organisation to function as was
the case before the change
Bottom-up change
This is localised change that originates from
those at the coalface rather than change
initiated by management
British Telecom (BT) BT is the LSP for Cerner Millennium and also
provides the Spine and N3 functionality.
Care pathway
Standardised patient management practices
based on best available evidence for patients
with particular conditions as they progress
through the healthcare system
NHS Care Records Service (NHS CRS)
The electronic health record planned to be
introduced as part of the NPfIT. This is
planned to allow access of to health records
across care settings and consists of the
summary care record (planned to be shared
nationally) and the detailed care record (to be
held locally).
Case An NHS institution in which NHS CRS (RiO,
Lorenzo or Cerner) was, has, or is planning
to be implemented, where we undertook data
collection. This refers to the Trust and may
also include its immediate environment (e.g.
management, implementation team
members, other Trust staff including users of
277
the technology), may also include the local
primary care organisation and have several
sites (e.g. hospitals) within it
Cerner Millennium
Electronic Health Record software produced
by Cerner in the US and implemented
through BT in the UK as part of the National
Programme. It was originally an American
billing system.
Change Control Notice (CNN) National contract re-sets
Change Management
A managed approach to introducing change
Choose and Book (C&B) ¹ One of NPfIT’s headline deliverables. An e-
booking system operating across the NHS to
give patients more choice and control over
hospital appointments
Clinical documentation (CDC) Documenting care procedures, treatments
and future plans. NHS CRS software allows
this to be done electronically through Clinical
Documentation forms.
Clinical information system ¹ Refers exclusively to the information
regarding the care of a patient, rather than
administrative data, this hospital-based
information system is designed to collect and
organise data
Cluster
A grouping – in the context of the National
Programme, this refers to a geographical
grouping of areas that implement different
EHR software. They include London, the
South and the North, Midlands and Eastern
(NME) region of the country. The term was
initially used by NS CFH but later replaced by
‘geographical region’.
Coding
The process of structuring information for
statistical analysis purposes. This is often not
visible to the end-user.
Computerised (electronic) decision Software applications that integrate patient
278
support systems (CDSS) ¹ data (input) with a knowledge-base and an
inference mechanism to produce patient
specific output in the form of care
recommendations, assessments, alerts and
reminders to actively support practitioners in
clinical decision-making
Compatibility ¹ Refers to the ability of two pieces of
hardware (a personal computer and a printer,
for example) to work together. Standards,
published specifications of procedures,
equipment interfaces, and data formats are
essential to decreasing and possibly
eventually extinguishing incompatibility.
Computer network ¹
An interconnection of a group of computers.
Networks may be classified by what is called
the network layer at which they operate
according to basic reference models
considered as standards in the industry.
Computerised medical record ¹
This involves transferring paper documents
into a computer system. This is done either
through handwriting or transcription and is
transferred into digital form with image
scanning, optical character recognition
scanning, or hybrid systems of these
Computer Sciences Corporation (CSC) ¹
The LSP for the North West and West
Midlands Cluster and North East and Eastern
Clusters, delivering software developed by its
main subcontractor iSOFT.
Connectivity ¹
The ability to send and receive information
between two locations, devices, or business
services
Customisation
The ability of a user or organisation to tailor a
system to their needs.
Data¹
In computer science, data is any information
in a form suitable for use with a computer.
Data is often distinguished from programs.
279
Data cleansing
Going through data and removing incorrect
data
Data migration
Transfer of data between two systems e.g.
from iPM to Lorenzo
Data quality Refers the data’s fitness for purpose
including completeness, validity, consistency,
timeliness and accuracy.
Department of Health (DH) A central governmental body managing the
NHS in relation to both funding and strategic
direction.
Deployment verification period (DVP)
A minimum of 45 day “deployment
verification period” (DVP) throughout which
the software, management and the impact on
the organisation is assessed. To assess the
success of the new solution against a set of
pre-defined verification criteria (both technical
and non-technical). This stage represents the
transition of support from the project team to
the data centre support and help desk teams.
Developer
Those that produce the software and as part
of this write and manage the code including
iSOFT (Lorenzo), CSE Healthcare (RiO) and
Cerner (Millennium).
Detailed care record (DCR) ¹ All notes taken from a patient by healthcare
professionals can be considered as the
patient’s detailed care record. The degree to
which this record is accessible by a
healthcare professional depends on whether
they are providing the patient with care, their
role in the treatment given and the patient’s
own wishes
Download ¹
The process of transferring files or software
from another computer to your computer
Early Adopter
Trusts that pilot Lorenzo in a clinical
environment and work with the developers
(iSOFT) and the LSP (CSC) to make it fit for
280
clinical use by feeding back any arising
problems. They get a Deployment Incentive
Fund” (DIF) of £1 million issued by NHS CFH
and are part of the so-called Lorenzo Early
Adopter Programme (LEAP). In the context of
the current project, we will use the term ‘early
adopter’ in a broader sense to refer to
organisations that were amongst the first to
implement the NHS CRS systems as part of
the NPfIT.
eHealth ¹
A relatively recent term for healthcare
practice which is supported by electronic
processes and communication. The term is
inconsistently used: some would argue it is
interchangeable with healthcare informatics,
while others use it in the narrower sense of
healthcare practice using the Internet. The
term can encompass a range of services that
are at the edge of medicine/healthcare and
information technology
Early Implementer
Or ‘fast follower’. These are Trusts that
implement after the ‘early adopters’ of
Lorenzo. The Deployment Incentive Fund of
£1 million issued by NHS CFH, is not
provided to ‘early implementers’.
Electronic health records Also referred to as Electronic Patient Record.
This is a compilation of patient information in
digital format that can be shared between
care settings. May also have additional
functionality.
Electronic patient record (EPR) ¹
The EPR concept grew out of the CPR
concept and, for a while, was the main term
used. Now, some consider this term
synonymous to the CPR term; however, an
increasing number of individuals state that
the EPR vision differs from the CPR
281
Electronic prescribing (ePrescribing) ¹
The use of computing devices to enter,
modify, review and output or communicate
prescriptions
Error ¹ An act of commission (doing something
wrong) or omission (failing to do the right
thing) that leads to an undesirable outcome
or significant potential for such an outcome
Foundation Trust
Currently there are 129. These Trusts have
increased responsibility and are accountable
directly to the Department of Health.
GP2GP¹
Part of NPfIT. Enables patients’ EHRs to be
transferred directly from one practice to
another
Handhelds
A portable device with the capability to hold
Electronic Health Record software.
Healthcare professional Refers to clinical staff only such as doctors,
nurses, allied health professions etc.
Health informatics—or medical
informatics ¹
Is the intersection of information science,
computer science and healthcare
Implementation
The process of introducing a new system
within an organisation (from planning through
to routine use).
Implementation team
Those individuals within a Trust that manage
the implementation of a new system locally.
Information Technology (IT) ¹
Defined by the Information Technology
Association of America (ITAA) as “the study,
design, development, implementation,
support or management of computer-based
information systems, particularly software
applications and computer hardware.” IT
deals with the use of electronic computers
and computer software 581to convert, store,
protect, process, transmit and retrieve
information, securely
Integrated Clinical Pathway (ICP) Used in different contexts with different
meanings. From a technical perspective, in
282
the context of the NHS CRS, it was used to
refer to automated workflows along a
patient’s journey of care, that integrate
clinical and administrative work.
Interface ¹ The connection between two devices; applies
to both hardware and software. May also
refer to what is visualised on a screen – what
the user will see and use to interact with the
software (see also user interface)
Interim system
An electronic system with basic functionality,
installed as a first step towards the final
Electronic Health Record solution designed
to deliver some early benefits to Trusts but
planned to be substituted by the final solution
eventually. Includes iPM.
Infrastructure
The existing organisational systems present
on top of which a new system is introduced.
This may include hardware or existing
systems such as Wi-Fi.
Interfaces
Providing a connection between two different
systems so that the display allows the user to
interact with both systems in a more
integrated way.
Interoperability
Systems’ ability to work along side each
other in an integrated way. See also
‘compatibility’
Issue Management Process (IMP) ‘Early adopter’ sites of Lorenzo would get
new builds of the system on a regular basis
and test them in the testing environment
before they went live to the live environment.
During this process they collected any issues
that emerged either from the testing or from
the actual use of each build. These issues
were then prioritised and kept by each ‘early
adopter’ site in a log and were collectively
managed by ‘early adopter’ sites, NHS CFH,
283
CSC and SHA through what they called the
Issue Management Process (IMP). These
issues would be reported to CSC, which
would then report them to iSOFT in order to
be fixed. The process however was not as
smooth as presented here.
iPM The interim PAS supplied by the CSC. This
eventually gets replaced with the Lorenzo
PAS.
iSOFT The developer of Lorenzo, managed through
CSC.
Legacy system
An old system that is still used despite newer
ones being around.
Legitimate relationships/role based
access (RBAC)
Security of accessing Electronic Health
Records in England is based on legitimate
relationships. This means that only users
who have legitimate relationships with
particular patients have the authority to
access their records.
Local Service Provider (LSP) These hold contracts with NHS CFH are
responsible for delivering solutions on the
ground
Lorenzo
Electronic Health Record software produced
by the Computer Sciences Corporation and
implemented through BT in the UK as part of
the National Programme. It was originally an
American billing system.
Mental Health Trust A Trust that provides mental health services
National Health Service (NHS) The National Health Service (NHS) in the UK
was established in 1948 with the aim to
provide “free” national care for all. Funding is
obtained from the taxpayer and managed by
the Department of Health. The NHS England
functions independently from the NHS
Scotland and the NHS Wales.
National Local Ownership Programme NLOP was set up by the DH in order to
284
(NLOP) increase local ownership, share risk and pool
resources (financial, expertise, support etc.)
locally that relate to the implementation of
NPfIT components. The shared funds were
planned to be held by local SHAs and
distributed to individual Trusts on an “as
needed” basis.
National Programme for IT (NPfIT) ¹
Is responsible for procurement and delivery
of the multi-billion pound investment in new
information and technology systems to
improve the NHS
Network ¹
A set of nodes, points or locations which are
connected via data, voice, and video
communications for the purpose of
exchanging information. Interconnected
telecommunications equipment used for data
and information exchange. Consists of
different types, LAN, MAN, and, WAN being
examples
NHS Connecting for Health (NHS CFH) ¹
Supports the NHS to deliver better, safer
care to patients, via new computer systems
and services, that link GPs and community
services to hospitals
NHS number
A unique identifier for any given patient in
England used to find associated patient
records
Output-based specification (OBS) ¹
Each prospective supplier to the National
Programme must meet rigorous technical
requirements. These are set out in an output-
based specification
Patient Administration System (PAS)
A basic electronic system in a hospital that
hold patient demographic details and can
manage admissions
Personal Demographics Service (PDS)
Holds patient demographic information and
patients’ NHS number. It is a component of
the Spine, which means that this information
285
is planned to be shared nationally.
Picture Archiving and Communications
System (PACS) ¹
One of NPfIT’s headline deliverables. A
system capable of acquiring, transmitting,
storing, retrieving, and displaying digital
images and relevant patient data from
various imaging sources and communicates
the information over a network.
Pilot
A small scale preliminary test to see if
something works, before rolling it out of a
larger scale.
Primary Care Trust A Trust that provides primary care services
Process mapping
Analysis and outline (typically in a flow chart)
of a business process resulting in a visual
outline of the steps involved to accomplish a
particular task.
Product Specialist
Those with intimate knowledge of the product
(e.g. the software).
Program ¹
Set of instructions that detail a task for the
computer to perform. In this sense, data is
thus everything that is not programme code.
Project Initiation Document (PID)
A written plan of an organisational project.
Typically follows a structured format outlining
present and future states, anticipated
benefits, anticipated resources and an
approximate timeline.
Requests and results (R&R)
Functionality that allows electronic requests
and receiving of results in hospitals. Typically
these include radiology, endoscopy and
pathology.
Roll-out ¹
The period and activities of progressively
going live in each cluster starting with the
‘early adopters’. This is backed by the user
training by the NHS LSPs.
Secondary Uses Service
Collection of data held in electronic health
records on a national level and using this
data for reporting of national trends and
286
statistical analysis.
Server
Software programme that is the basis for
other computer programmes. This can take
the form of holding files, managing printers or
network traffic.
‘Soft landing’ Deploying systems on a small scale running
the clinical process in parallel with existing
systems and paper initially.
Software build Different versions of the software released by
the developer. These typically present an
improvement on the previous version.
Software fixes Minor changes made to the solution by the
developer to respond to emerging local
issues. Also called patches.
Software releases
Different components of the software with
increasing capabilities. These are designed
to be implemented sequentially in order to
promote stepwise change.
Spine ¹
The name given to the national database of
key information about a patient’s health and
care and forms the core of the NHS Care
Records Service. It will include patient
information like NHS number, date of birth,
name and address, and clinical information
such as allergies, adverse drug reactions and
major treatments.
Standards (interoperability)
Software requirements necessary for
achieving interoperability between systems.
Standardisation Complying with a certain standard.
Strategic Health Authority (SHA)
At a local level the English NHS is managed
through 10 Strategic Health Authorities
(SHAs) and Trusts, whose responsibility it is
to ensure that national plans are
implemented locally and that local needs are
reflected in policy developments.
Summary Care Record (SCR) ¹ A key element of the NHS Care Record
287
System. The General Practice summary will
be the main or only active part of the SCR; in
time it will be supplemented by other
contributions. Over time, a SCR will be built
up from selected information in a patient’s
Detailed Care Record. The SCR can be seen
by authorised healthcare professionals
treating patients anywhere in England, if
patients wish them to.
System upgrades
Software typically performs better after an
upgrade than it did before an upgrade.
Testing environment
Testing particular software in an artificial
environment to determine how it performs
before deploying it.
Top-down change
This is hierarchically imposed change
initiated by management.
To-take-out medication
Part of the prescribing functionality in the
NHS CRS. This is medication that the ward
orders electronically from the pharmacy that
then dispenses it for the patient to take
home. Also known as TTA (To Take Away).
Trust board
A committee in a Trust that has decision
making powers.
Trust site
Refers to hospitals/healthcare organisations
within the Trust
Trust staff
Refers to all Trust staff including IT, admin,
and all other staff, this also includes
healthcare staff
User authentification ¹
The process of ensuring an end user is
actually the person he/she purports to be.
User interface ¹
The graphic and design components of a
Web page that directs users on how to
access the information contained in that Web
site
Virtual private network (VPN) ¹
A communications network using a tunnelling
protocol through another network, dedicated
288
for a specific network
WES criteria Software and hardware criteria specified by
CSC that the Trusts need to comply to in
order for Lorenzo to work successfully in the
specific setting.
Workflow
A chain of steps/activities involved to
accomplish a particular task.
¹ These definitions have been adopted from the NHS CFHEP 001 report available from:
http://www1.imperial.ac.uk/resources/1636368E-DDEE-42A0-85AC-BDE9EC3B9EA1/
289
Appendices and supporting material
Appendix 1: Work-package aims and objectives
Original Aims and objectives
The main original aims of our proposed project were to inform the roll-out of NHS CRS with a
view to ensuring that this is successfully used and has the maximum chances of introducing
benefits whilst minimising harm. In doing so, we were planning to:
• Identify benefits and negative impacts of the new system across a variety of
dimensions that were reflected in our work-packages
• Liaise with NHS CFH throughout the project in order to inform both local
implementation and national roll-out of the NHS CRS.
The call for proposals presented some indicative research questions, which we have
incorporated in six complementary work-packages described below. More generally, we saw
these work-packages (WPs) as closely related and, where appropriate, as sharing
theoretical approaches, field work activities in data collection, and analytical themes.
The specific objectives that we proposed to focus on were to:
WP1: Implementation, deployment and organisational learning
• Identify and document the implementation strategy in use and its justification, and the
balance of planned versus emergent change supported.
• Identify the stages through which implementations proceed, both planned and actual,
and the criteria used to progress between stages.
• Identify assimilation gaps and the strategies used to address them
• Identify relevant activities and deliverables at each stage (process and outcomes)
• Assess how safety, patient care and organisational context is incorporated in to
implementation activity
• Identify examples of organisational learning and the development of new
competencies (technical and evaluative)
• Feedback all the above to support the continuing roll-out of NHS CRS.
290
WP2: Stakeholder attitudes, expectations, engagement and satisfaction
• Explore key stakeholders’ (i.e. including patients/carers, healthcare professionals and
managers) attitudes and expectations of the NHS CRS in secondary care before it is
introduced
• Explore their early experiences of the NHS CRS
• Explore their perceptions once the system has become established and, where
applicable, once they have become experienced users of the new system
• Feedback all the above to support the continuing roll-out of NHS CRS in secondary
care.
WP3: Organisational consequences: organisational workflow, professional role and data
quality transformations
• Explore how human resource transformations occur in terms of evolving professional
roles and remits
• Explore how workflows transform
• Investigate the impact of NHS CRS on the IT literacy of the staff involved
• Understand the changing IT training needs of healthcare professionals
• Investigate the impact of introduction of NHS CRS on data quality.
WP4: Assessment of costs of NHS CRS implementation
We seek to:
• Assess exceptional introduction per-provider costs
• Assess annual (recurring) per-provider costs
• Develop evaluation frameworks to assess the impact of NHS CRS on costs
• Validate cost categories with local providers and with NHS CFH
• Make recommendations about a core dataset for NHS CRS evaluation post-
implementation.
WP5: Assessing error, safety and quality of care
• Investigate whether the introduction of the NHS CRS results in improvement in
medicine reconciliation on admission to, and discharge from, hospital
• Investigate whether the introduction of the NHS CRS results in improvement in
availability of clinical records
• Investigate whether the introduction of the NHS CRS results in improvement in
availability of clinical test results in secondary care outpatient and inpatient settings.
291
WP6: Organisational consequences and implications for future IT deployments and
evaluations
• Summarise and integrate the findings from the previous five Work Packages
• Identify barriers and drivers that shape the implementation process and drive the
diffusion of NHS CRS within the health community
• Relate findings to the overall objectives of the NHS CRS and NHS CFH – e.g. for
seamless care, efficiency gains, error reduction, guideline adherence, disease
surveillance etc.
• Assess the degree of transformation of the healthcare system that NHS CRS and
associated projects may lead to
• Draw conclusions in respect of governance and communications strategies related to
implementations of this scale and complexity
• Identify relevant target audiences for this research, and their specific needs and
interests
• Prepare reports and other materials relevant to these audiences and from which they
can draw in future work.
292
Appendix 2: Ethical approval for this evaluation
Document
Description
Document file name Author
1. Documents relating to application to Ethics Comm ittee for approval for this evaluation
1.1 96 page
document
submitted for
ethics approval
SheikhNHSCFHEP005finalversion216thMayconfidential
with appendix removed
Kathrin
Cresswell
1.2 Letter re: review
of application,
confirmation of
committee
hearing date
Valid App 17-09-08
Miss Sandra
Burke, East
London and the
City Research
Ethics
Committee 1
1.3 Letter re:
documents
submitted for
consideration.
Not within remit 09-10-08
Miss Sandra
Burke, East
London and the
City Research
Ethics
Committee 1
1.4 Initial Study
registration
proforma for
registration with
UK National
Institute for
Health
Research
(NIHR) Clinical
Research
Network
(UKCRN)
28th February
2008.
UKCRN Clinical Studies Portfolio – initial study proforma
1.5 Second Study UKCRN Clinical Studies Portfolio – initial study proforma
293
registration
proforma for
NIHR UKCRN
26th September
2008.
1.6 Response from
NIHR UKCRN
14th October
2009.
UKCRN Response letter confirming study eligible
Dr Sam Taylor,
Portfolio Lead,
NIHR Clinical
Research
Coordinating
Centre
2. Documents relating to PhD
2.1 Application for
ethical approval
RecForm_ReadyForSubmissionv5PhD
2.1 Ethical approval
letter
Ethical approval letter 02-04-09 A T Tucker,
Senior
Research
Ethics
Administrator,
East London
and The City
Research
Ethics
Committee 1
294
Appendix 3: Research and development approval docum ents by site
No. Site Document file name
1. A Hon.contract – Ann Robertson (Honorary Appointment letter)
2. B Site B permissions email 03-03-09
3. B Site B Caldecott Guardian approval email 30-03-09
4. B Site B site access docs
5. C Site C access approval email 06-04-09
6. C Site C permission from board Minutes_EAProjectBoard_20.03.09
7. C Site C Caldecott guardian approval email 20-04-09
8. H Site H access approval email from PCT 24-07-09
9. H 1302 - non-NHS LoA SBPCT-P [K.Cresswell] 04.01.10
10. H Site H 1302-14067_NHS_RM&G_Permission_Letter_SBPCT_10-12-09[1]
11. H 1302 - RM&G Permission Letter SBPCT-P 04.01.10
12. P Trust P-Letter-Of-Access-p1 (Access approval letter)
13. P Trust P-Letter-Of-Access-p2 (Access approval letter)
14. P Trust P-Letter-Of-Access-p3
Completed honorary contract request form including researcher CV.
15. P Trust P-Letter-Of-Access-220110 (Access approval letter)
16. Q Site Q - email 20-01-10
17. Q Site Q - Trust approval letter 16-07-10
18. X Site X – Permission email correspondence
295
Appendix 4: Summary of individual case studies
Title Case Study of Trust A
Study period Between February 2009 and November 2010
Region (Cluster) London
Type of Trust
(attributes)
Large, multi-site, urban, acute NHS Trust
Number of sites 5 hospitals (3 acute hospitals)
Systems
implemented under
NHS CRS Programme
and timeline
This Trust is to implement Millennium under the Programme’s New
Delivery Model for London. The staged, first implementation
phase, due to start at the end of March 2011, is planned to include
order communications, then a Trust-wide Patient Administration
System, clinical documentation, care planning, medicines
management and maternity systems, plus additional Cerner tools
(MPages). The deployment of further Millennium functionality is
planned during a follow-on, second, staged phase.
Early Adopter/Fast
Follower
Still to deploy
Research method 30 interviews were conducted, 26 with a range of Trust
implementation team, clinical and administrative staff, and patients
and carers, and 4 with Cerner and the Local Service Provider, BT.
Additional data were gathered through attending Trust meetings
and collecting Trust documents.
Work-package(s) WP1, WP2, WP3
Key Contributions Site A is a relatively new and evolving organisation, following a
major merger in 2007 and subsequent innovations. Hence its NHS
CRS implementation plans have been strongly influenced by
external factors – delays and changes to the London Programme –
and internal factors – the changing organisation. The repeated
revisions and delays to this Site’s deployment plans can be seen
to have incurred frustration and staff disengagement on the one
hand but, with hindsight, have also allowed this organisation
valuable extra time in which to prepare more thoroughly for the
imminent implementation.
296
Title Case Study of Trust B
Study period Between February 2009 and November 2010
Region (Cluster) NME
Type of Trust
(attributes)
Large acute Trust providing care in a predominantly rural,
geographically scattered and disparate community.
Number of sites 3
Systems
implemented under
NHS CRS Programme
and timeline
This was the first English acute Trust to pilot Lorenzo. It has begun
implementing Release 1 as a ‘soft landing’, running the system in
parallel with existing paper systems, in one surgical ward at the
end of October 2008. This was followed by go-live at another
surgical ward at the end of April 2009, and an orthopaedic ward in
June 2009. At time 2 interviews, the Trust had moved to using
R1.9 which replaced iPM with the Lorenzo PAS in all areas and
locations except A&E. This was the first implementation of R1.9 in
an acute setting, a Trust-wide undertaking with a user base of
3,500.
Early Adopter/Fast
Follower
Early Adopter
Research method Interviews with a total of 58 Trust staff including users and
implementation team members were conducted. Complementary
to these, Trust and press documents as well as researcher field
notes and observation notes allowed gaining an insight into the
specific context of implementation. We also conducted 5
interviews with patients and collected 2048 questionnaires.
Work-package(s) WP1, WP2, WP3, WP4, WP5
Key Contributions The implementation has not been without challenges. This has
become particularly clear over time, as the user base and the
software functionality increased and the national strategy has
evolved. The focus of this case study is the exploration of a
seemingly paradoxical attempt to implement non-existent software
on a large scale in a complex acute setting, exploring the
implications for stakeholders on the ground as well as for the
Programme as a whole. It is argued that the most important factor
contributing to the lack of progress and problems perceived by
users are basic issues with stability and usability of the software
297
with development being constrained by national contracts.
Technical issues encountered have in turn have impacted on
social dimensions such as attitudes, engagement, motivation and
ultimately on the perceived success of the Programme as a whole.
298
Title Case Study of Trust C
Study period May-August 2009 and March-June 2010
Region (Cluster) NME
Type of Trust
(attributes)
Large acute Trust providing care to over 1 million people in the
community
Number of sites 2
Systems
implemented under
NHS CRS Programme
and timeline
The Trust implemented Lorenzo Release 1 (LR1) by following a
‘small scale’ approach. LR1 went live in March 2009 and was used
for ordering X-Ray requests and reporting results for post-
operative hip and knee joint replacements for out-patients and
elective inpatient cases. By June 2010 LR1 was being used Trust-
wide for uploading VT assessments for inpatients and for
reporting. In December 2009 the Trust initiated the Clinical
Documentation Project, which intended to digitalise the hip and
knee pathway before moving to other pathways within the
Orthopaedics and other departments.
Early Adopter/Fast
Follower
Early Adopter
Research method Semi-structured interviews with 23 Trust staff, including users and
implementation team members, and Trust-related documents.
Work-package(s) WP1, WP2, WP3
Key Contributions We found that configuration was a political process during which
interpretations of different groups of people were continuously
exchanged and negotiated. In doing so they brought about
constant changes in the assumptions inscribed into CRS. Cultures
(national and organisational), work ethics (business and
professional) and knowledge (or lack) of business processes were
important enablers and constrainers of configuration. LR1 brought
about some subtle yet important changes in healthcare
professionals’ work. It conditioned computerisation of work
practices, users’ informatisation and standardisation of their
conduct, influenced the extent to which they can exercise
discretion and provided visibility over their and peers’ work.
299
Title Case Study of Trust D
Study period December 2009- December 2010
Region (Cluster) London
Type of Trust
(attributes)
Medium acute Trust providing all areas of care located in an urban
and affluent area in Great London with 520 beds, 3000 staff, and
320,000 caring population
Number of sites 2
Systems
implemented under
NHS CRS Programme
and timeline
First London acute Trust to go-live with LC1 upgrade of Millennium
in London after the NHS CRS was put on hold due to a
problematic deployment of LC1 in another first of type Trust. The
hospital went live on the final day of November 2009, the very
latest that director general of informatics, at the DH, said that
Local Service Providers (LSP) BT and CSC were given to make
“significant process” with their strategic systems under the
National Programme for Information Technology (NPfIT).
Early Adopter/Fast
Follower
Early Adopter
Research method 34 semi-structured face to face interviews with various
stakeholders at different levels inside and outside the Trust
including LPfIT, Cerner, and BT; content analysis of over 900
pages of hospital documents; and 22 hours of field observations.
Distribution of the Clinical Computer Systems Survey, to gather
users’ feedback on Millennium, and more generally assess
dimensions of use and usability of hospital clinical systems.
Work-package(s) WP1, WP2, WP3, WP4
Key Contributions Multiple perceptions and visions of the NHS CRS were revealed,
resulting in stakeholders’ multiple views about EHRs. The role of
the experienced leadership was crucial to move the
implementation of NHS CRS forward. From the outset, the senior
management of the hospital described the NHS CRS as a means
of change management and “as a vehicle for improving the
hospital performance”. The strategy was not “thinking too much
about IT, rather making sure that the IT is robust underneath”. The
hospital paid particular attention to organisational learning and
focused on ‘here and now’ rather than potential, future benefits.
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The hospital negotiated for a meaningful local configuration of the
NHS CRS. The main problems were inadequate software,
disintegrated NHS IT, and local resistance. The senior
management was clear that it might take them at least 10 years to
adopt an EHR system and to realise clearly discernible benefits.
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Title Case Study of Trust E
Study period May 2009- December 2010
Region (Cluster) London
Type of Trust
(attributes)
Large acute Trust providing all areas of care located in an urban
and affluent area in north London with 900 beds, 5000 staff, and
700,000 caring population
Number of sites 1
Systems
implemented under
NHS CRS Programme
and timeline
“First of type’ acute Trust in England to go-live with LC1 upgrade
of Millennium, which was the first version of Millennium with Spine
connectivity. The hospital went live in June 2008 with PAS,
Maternity, A&E (Firstnet), Surginet (theatres), order
communications, and live bed management on Millennium. The
Trust will also be first acute Trust to implement e-prescribing
module of Millennium in London.
Early Adopter/Fast
Follower
Early Adopter
Research method 27 semi-structured face to face interviews with various
stakeholders at different levels inside and outside the Trust
including LPfIT, Cerner, and BT; content analysis of over 750
pages of hospital documents; and 19 hours of field observations.
Work-package(s) WP1, WP2, WP3, WP4
Key Contributions Multiple perceptions and visions of the NHS CRS were revealed,
resulting in stakeholders’ multiple views about EHRs. The Trust
considered the NHS CRS as another big IT project and felt
confident to move it forward. This led to overestimating the
capabilities at the Trust level and underestimating the required
level of preparation prior to go-live. The vision to the NHS CRS
was linear and the role of human and cultural factors to adopt
EHRs was overlooked. The Trust put the NHS CRS business case
with minimum insight and information, as it was pushed to switch
to LC1 half way through the implementation, which had been
planned for LC0. Users were reluctant to get engaged with the
solution which resulted in many workarounds. Even though the
Trust experienced a very problematic and costly NHS CRS
implementation, lessons learned at Site E proved to shine the way
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for follower adopters in London.
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Title Case Study of Trust G
Study period Between October 2009 and October 2010
Region (Cluster) London
Type of Trust
(attributes)
Large, multi-site, urban, mental health NHS Trust
Number of sites 5 main service delivery units
Systems
implemented under
NHS CRS Programme
and timeline
This Trust has implemented the web-based, mental health
application from CSE Healthcare (formerly CSE Servelac), and
upgraded from RiO version 4 to RiO version 5. In the course of the
remainder of the Programme, the Trust is due to receive 15
(London-wide) configuration releases to update the system.
Early Adopter/Fast
Follower
Early adopter of basic version of RiO (version 4)
Research method This was a less in-depth case study, with data sources including 6
interviews with Trust staff (implementation team and clinical staff)
and 2 interviews with the Local Service Provider, BT, plus Trust
documents.
Work-package(s) WP1, WP2, WP3
Key Contributions Site G gives some insights into the frustrations and challenges
perceived by some of those receiving RiO mental health systems
through the Programme, despite RiO often being presented as a
“success” of the London Programme by others, and some insights
into a Trust’s support needs when undergoing a major IT-system
upgrade. It highlights a perceived need for far greater openness
about “failures” and sharing lessons learned in order to avoid
future repetitions of similar problems.
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Title Case Study of Trust H
Study period Between July 2009 and July 2010
Case Trust H
Region (Cluster) NME
Type of Trust
(attributes)
A large urban Primary Care Trust commissioning both regional
and specialty services.
Number of sites 1
Systems
implemented under
NHS CRS Programme
and timeline
Ten healthcare professionals were the first individuals to ever use
the newly developed Lorenzo R1 in a clinical context on the 3rd of
September 2008. This was initially planned to be a three month
pilot of the system but is, as of October 2010, still ongoing. The
rest of the podiatry team started using Lorenzo in May 2010 and
was until then still using paper systems.
Early Adopter/Fast
Follower
Early Adopter
Research method Interviews with a total of 24 Trust staff including healthcare
professionals and implementation team members were conducted
and analysed in combination with over 600 pages of Trust
documentation, researcher field notes, observation notes and
articles in the media. We also conducted 28 interviews with
patients.
Work-package(s) WP1, WP2, WP3, WP4
Key Contributions This small scale and resource-intensive implementation gives an
insight into issues surrounding sustainability and scalability of
implementation approaches. It illustrates that, whilst significant
efforts can help to integrate the software with existing work
practices locally, implementation success is not only characterised
by sociotechnical considerations in the micro environment but also
by the potential of transferability to other settings as well as
sustainability in terms of resources, which in turn impacts on local
arrangements.
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Title Case Study of Trust M
Study period May 2009- November 2010
Region (Cluster) London
Type of Trust
(attributes)
A large mental health and social services Foundation Trust
providing all areas of mental healthcare and social services with
some 1,800 staff who work in over 110 teams spread out into 34
sites across the two boroughs located in an urban area in north
London that serves 515,000 population.
Number of sites 2 hospitals and 4 community centres across two boroughs
Systems implemented
under NHS CRS
Programme and
timeline
7th (out of 10) mental health Trust that went live on RiO in London
and 1st London Trust who went live with RiO 5.1 which had Spine
connectivity. The Trust went live in two main phases in December
2008 and September 2009. The Trust will also be the first mental
health Trust to implement e-prescribing module of RiO in London.
Early Adopter/Fast
Follower
Fast Follower
Research method 48 semi-structured face to face interviews with various
stakeholders at different levels inside and outside the Trust
including LPfIT, CSE Health International, and BT; content
analysis of over 1100 pages of hospital documents; and 26 hours
of field observations.
Work-package(s) WP1, WP2, WP3, WP4, e-prescribing (ep) pilot
Key Contributions Given a general poor history of EHRs in mental health sector,
arrival of NHS CRS was well welcome at Trust M. Although the
project management and leadership of the Trust were praised
because of their insight towards the Programme, the overall
professional competence of the managers might have been
limited to general IT project experience. Compared to acute trusts
and other mental health trusts in London that moaned a great
deal about NHS CRS and mainly experienced pain, Site M was
perceived to have had a smooth and continuously improving
implementation of RiO. Our evaluation found that the Trust was
determined to make RiO work in the organisation and did not
dream that it would deliver many short-term benefits. Modest
expectation, appropriate infrastructure and preparedness;
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continuous analysis to address issues and shortages plus a clear
desire from the leadership to make EHRs work all contributed to a
successful implementation of RiO at Site M. ePrescribing was
also perceived to be beneficial for patients’ safety and to have the
potential for reducing error. However, it was at a very early pilot
stage when we evaluated the module.
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Title Case Study of Trust P
Study period January - August 2010
Region (Cluster) South
Type of Trust
(attributes)
Large acute Foundation Trust (teaching hospitals), providing care
in a geographically scattered community
Number of sites 5
Systems
implemented under
NHS CRS Programme
and timeline
The Trust was planning to implement Millennium with Fujitsu but
the implementation never began.
Early Adopter/Fast
Follower
n/a
Research method Focus on the integrated stroke pathway and the use of information
and technology for the pathway. Data collected through
observation and unstructured interviews. Documents available on
the Web were consulted to inform analysis of history of the Trust
and the wider context.
Work-package(s) WP1, WP2, WP3
Key Contributions The case study offers:
• Insight into how a stroke pathway unfolds in practice in an
acute setting, and the use of, and needs for, information
and technology for clinical and administrative work;
challenges of workflow automation; needs for reporting
functionalities.
• Insight into the processes of technology adoption and use:
beyond the software interface, to the combination of
hardware, space, and people; the difficulty of replacing
communication with computerisation; transformations in the
nature of work; and possible issues of ‘image’ computers
project to colleagues and patients.
• Questions on the meaning of the term pathway, used to
signify the whole (the entire flow) and/or its parts (e.g. a
Thrombolysis set of paper forms), as well as the whole in
prospect (e.g. the care plan) or in retrospect (e.g the care
provided).
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Title Case Study of Trust Q
Study period Between December 2009 and November 2010
Case Trust Q
Region (Cluster) NME
Type of Trust
(attributes)
Mental Health Trust providing day care, in-patient care and
community services (including services in patient’s homes) over a
large geographical area.
Number of sites 3
Systems
implemented under
NHS CRS
Programme and
timeline
Trust Q was the first mental health Trust to use Lorenzo and the
fourth Trust to ever use Lorenzo software. It went live on the 28th
September 2009 with Lorenzo R1 and deployed to all five
community teams of one of their services. The deployment of R1
was viewed as a pilot deployment before the other Trust services
went live. There were initially about 140 end users (the largest user
base of Lorenzo R1 anywhere), which is still accurate as of
November 2010.
Early Adopter/Fast
Follower
Fast Follower
Research method Interviews with a total of 20 different Trust staff including users and
implementation team members were conducted and analysed in
combination with Trust documentation, researcher field notes,
observation notes and media articles.
Work-package(s) WP1, WP2, WP3, WP4
Key Contributions National arrangements have impacted on the progress of local
implementation activities and use of the software.
The Trust had, despite adequate local resourcing and motivation to
proceed, initially succeeded in implementing the software on a
relatively large scale.
However, over time it became apparent that the progress of
implementation remained relatively static, and that users were
getting increasingly frustrated with software that was not perceived
as fit for purpose in its current state and led to significant changes
in work practices with several unintended consequences.
Fundamentally different assumption between organisational
stakeholders may have contributed to a lack of progress.
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Title Case Study of Site R
Study period February 2010 -November 2010
Region (Cluster) South
Type of Trust
(attributes)
Site R constitutes along with another hospital an acute Trust that
provides services to 250.000 people in the community
Number of sites 2
Systems
implemented under
NHS CRS Programme
and timeline
The Trust implemented Millennium Release 0 by following a ‘big-
bang’ approach. Millennium R.0 went live in March 2007. It offered
PAS and some clinical and administrative functionality. After 18
months the Trust merged with another hospital and decided to opt
out of Millennium implementation and turn to an upgraded version
of their previous PAS, a solution that all other hospitals within the
Trust used.
Early Adopter/Fast
Follower
Early Adopter
Research method Semi-structured interviews with 5 Trust staff, including IT,
management and clinical implementation team members, Trust-
related documents and articles from the media.
Work-package(s) WP1, WP2, WP3
Key Contributions The Site provides interesting insights into critical aspects of
managing NHS CRS implementation. These aspects were related
to the design of the software, the delivery mechanisms of the
software and the management of the implementation primarily at
an inter-organisational level but also at an intra-organisational
level. Specifically, some outstanding issues were related to the
lack of Trust’s choice concerning software solution, limited
functionalities of the software, difference between the assumptions
embedded in the system about clinical work practices and actual
clinical work practices, top down decision making process,
prioritisation of outcomes over processes, command and control
culture, rigid and undisclosed contractual restrictions and a culture
that obstructed knowledge sharing between adopter sites.
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Title Case Study of Trust X
Study period May 2010 and December 2011
Region (Cluster) NME
Type of Trust
(attributes)
Small acute Trust providing care in a predominantly rural,
geographically scattered and disparate community.
Number of sites 1
Systems
implemented under
NHS CRS Programme
and timeline
Early Adopter site developing use of Lorenzo R1.0 for clinical
documentation within one speciality and in relation to some
pathology services. Although the system fulfilled the ‘go-live’
contractual criteria for implementation in September 2010 paper
records continue to be used in parallel. Developments planned for
more extensive pathology ‘Requests and Results’ functionality
were planned for February 2011 but are now intended for end
March/ early April 2011. The current user base is small (n = <40)
and there is low awareness or curiosity regarding the system
amongst non-users. Dates for migration to R1.9 are not currently
decided.
Early Adopter/Fast
Follower
Early Adopter
Research method Longitudinal case study involving two separate visits to gather
data on-site. The first visit (T1) took place in May 2010, the second
(T2) in December 2010. During both T1 and T2, two researchers
simultaneously conducted qualitative interviews (n = 27) and
observations together with a quantitative study of case note
availability. In addition, documentary analysis of Trust, software
provider and press documents has been conducted.
Work-package(s) WP1, WP2, WP3, WP5.
Key Contributions Lorenzo software at this site has been studied with regard to the
adoption of electronic health records (EHRs) and the National
Health Service Care Records Service (NHS CRS). Work to
introduce Lorenzo would be described more accurately as
development rather than adoption. Whilst there was significant
local evidence of both the capacity and desire to implement EHRs,
software functionality was very limited, was felt to have taken far in
excess of the time intended and to have required an unanticipated
degree of service user input. Issues with the pace and quality of
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software engineering contributed to a significant lowering of
expectations of Lorenzo in the provision of EHRs and resultant
benefits to clinical care. During T1 it was very much discussed as
a focus for the future whereas during T2 it was described as only
one component of local EHR provision.
Development of Lorenzo appeared driven by regional and national
procurement and contractual obligations. There was a notable lack
of senior engagement in the Lorenzo project, with only isolated
examples of local leadership and no evident local strategy. There
was no evidence of Lorenzo positively impacting upon clinical care
nor patient experiences and outcomes.
Over the course of the study, technical difficulties and a lack of
strategic direction were further compounded by a changing
economic and political climate. This was apparent in a sense of
uncertainty regarding financial support for Lorenzo and concern
amongst staff that efforts to date would not be pursued to fruition
beyond the current financial year.
In summary, this small study illustrates a continued motivation
amongst more junior staff to successfully introduce changes to
their working practice that will improve patient care. A lack of
systems capability, the time taken to develop systems, lack of
leadership, clear strategic direction, staff awareness of the system
and financial uncertainty have contributed to staff prioritising
technical solutions that will deliver more immediate and expedient
local improvements in preference to that sourced through regional
procurement and defined by national strategy.
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Appendix 5: Interview topic guide: Work-Packages 1- 3: NHS Connecting For Health,
SHA and LSP staff
Interview guide for representatives of the LSP, Sof tware developers and SHAs
Please note that some themes of this guide may not apply for all LSPs, Software Companies
and SHAs due to the different nature of the software or service being provided.
Interviewee’s Background
Job role
Length in service
Implementation
Challenges that the LSP/Software houses/SHA faces concerning the development and
implementation of CRS software
Methodology followed for CRS software development
Testing process: steps, problems reported
Process of addressing issues that Early Adopter sites raise
Strengths and weaknesses of CRS software
Resources LSP has dedicated to early adopter sites
Software outsourcing
Perceptions
Role of LSP//Software houses/SHA in the Programme
Achievements from the adoption of NHS CRS software in early adopter sites
Issues/difficulties they faced from the adoption of CRS software in early adopter sites
Collaboration and communication process between different stakeholders (SHA, CFH,
Trusts)
Consequences of the political and economic context on the NPfIT and CRS
Contract: issues and obstacles
Lessons that can be transferred to future implementation sites/practices
Evolution of CRS in the future
Standardisation and/or localisation of the implementation process: views, rationale, benefits
and disbenefits.
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Appendix 6: Interview topic guide: Work-Packages 1- 3: Healthcare professionals and
managers
Interview Guide for Healthcare Professionals (and o ther users of the systems)
Note that sections in italic are common with section in Implementation Team Interview
Guide.
Interviewee’s Background:
• Current position in the organisation
• Relation to CRS
Background about the current status of CRS :
• Software
• Release
• Functionality being used & future upgrades [T2]
• Location of use and users (ward, clinics, departments etc)
• Previous systems that CRS software replaced and other current systems
• What systems did you have prior to CRS? What for?
• Are there any systems in place for patient management, like vital sign
monitoring; or is there going to be?
• What is the level of integration of existing systems, e,g together and with
CRS[T2]
[Some users – mostly the super users – have been in volved in the implementation
process. In this case, we also use the questions fr om the Implementation section ]
Use of NHS CRS software :
• Previous systems that NHS CRS software replaced
• How the interviewee uses the system
• Changes in the way you use the system [T2]
• Training received and ongoing support
• IT literacy and skills – your own – your team etc.
• Tasks carried out through the system
• Frequency of use/ conditions of use
• Initial, current and ongoing problems and concerns
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• Changes that the user would like to see happening in the system
• Role-based access & access to the Spine [T2]
Changes that the system has brought about :
• New tasks that have been added
• Old tasks that have been eliminated
• Same tasks done in a different ways
• Workarounds
• Modes of collaboration with other healthcare professionals
• Modes of interaction with patients
• Preparation of (new) standard operating procedures (T2)
Consequences of the NHS CRS on:
• Quality of Healthcare
• For Patients & patient pathways
• Healthcare professionals
• Trust
• Local Community
• Connection to and collaboration with GPs and PCTs [T2]
• Changes in your expectations [T2]
Perceptions
• NHS CRS in the future (local and national level)
• What would you do differently?
• Is it necessary?
• Is it worth it
• Benefits that you realised so far
• What is it all about?
Is the NHS CRS an end or a means for other changes
315
Appendix 7: Interview topic guide: Work-Packages 1- 3: Implementation Teams
Interview Guide for Members of the Implementation T eam
Interviewee’s Background :
• Current position in the organisation
• Relation to NHS CRS
Background to the current status of the NHS CRS :
• Software
• Release
• Functionality being used & future upgrades [T2]
• Location of use and users (ward, clinics, departments etc)
• Previous systems that NHS CRS software replaced and other current systems
o What systems did you have prior to NHS CRS? What for?
o Are there any systems in place for patient management, like vital sign
monitoring; or is there going to be?
o What is the level of integration of existing systems, together and with NHS
CRS[T2]
Implementation/Adoption :
• Decisions that were made (Who? What criteria?)
o What were the reasons behind NHS CRS/moving to Millennium/Rio/Lorenzo
o The way the business case was prepared; who participated, how approved?
And changes to that?
• Who involved in implementation (groups and people)
o IT literacy
• How
o Steps that were followed
o Methodology
� Factors that influenced the implementation process (e.g. history,
delays)
� Changes in the implementation strategy [T2]
� Issues of local configuration
• When (timeline)
• Incentives offered or given
316
• Resources used(human resources, financial)
• Changes in resources [T2]
• Training provided and ongoing support
• The method for training, real data or virtual – right software version?
Was any material provided? Who provided, What form?
• What is the Trust’s strategy for new staff who need to use NHS CRS?
Training, induction, SmartCard, etc.
• Management of data.
• Where are data kept and how are they managed? [T2]
• Collaboration within the organisation and across organisations:
• Software developer- LSP- NHS CFH- Trust:
• Interests (differences and similarities)
• Mechanisms to encourage collaboration; how do you work together?
• Issue management process (who, how, what problems, mechanisms
to resolve problems, examples of issues) [T2]
• Teething, current and ongoing problems
• What might be done differently?
• Awareness and Views about the contract
• Changes in the level of involvement of each organisation [T2]
• Early Adopters
• Feelings for being early adopter
• Mechanisms to facilitate collaboration among early adopter
• Lessons learned as used as input; as provided as output
• What can & cannot be learned & why?) [T2]
Consequences of the NHS CRS on :
• Quality of Healthcare
• For Patients & patient pathways
• Healthcare professionals
• Trust (management, strategy)
• Local Community
o Connection to and collaboration with health economy (GPs and PCTs) [T2]
• Changes in your expectations [T2]
Perceptions
• NHS CRS in the future (local and national level)
317
• What would you do differently?
• Is it necessary?
• Is it worth it?
• Benefits realised so far
• What is it all about?
• Is NHS CRS an end or a means for other changes
318
Appendix 8: Interview Topic Guide: Work-Packages 1- 3: Patients and Carers
Interview Guide for Patients and Carers
The following guides can be used for interviewing patients and/or their carers. The guide
includes themes to be discussed rather than specific questions. The interviewer is expected
to adjust some of these questions depending for instance on the setting where the interview
takes place i.e. waiting rooms, wards and the condition of the patient.
Background:
Patient/Carer
Location of the interview
Specialist/clinic they are seeing
Views :
Personal views about the process and quality of healthcare they receive (draw upon recent
and past experience).
Impression of whether hospitals are paper based, electronic or both. Functions for which
paper and technology are being used.
Perceptions about major changes that have taken place in the delivery of healthcare in the
last few years.
Feelings about having an electronic record as opposed to paper record.
Awareness of NHS CRS: source of information and understanding of it.
Expected benefits from electronic records.
Concerns about electronic records (safety, confidentiality etc).
Opportunities that electronic records may provide to patients, healthcare professionals &
Trusts.
Impact that CRS may have on their relationship with healthcare professionals.
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Appendix 9: Project Information Sheet
Evaluating the adoption of the NHS Care Records Ser vice in Secondary
Care
The introduction of electronic health records into NHS hospitals is a very important policy
development that is being pursued through NHS Connecting for Health. We seek the
opportunity to work with you and your Trust to evaluate the adoption of the NHS Care
Records Service (NHS CRS) in your hospital. This independent research is funded by the
NHS Connecting for Health Evaluation Programme and is being conducted by a team of
independent academics and clinicians from the Universities of Edinburgh, Nottingham and
London.
Through the various elements of this project we expect to learn some salient lessons about
the implementation and adoption of this important organisational transformation. We are
particularly interested in the attitudes, expectation and experiences of healthcare
professionals and IT personnel involved in all stages of the implementation of the new
technical systems that are being procured and introduced as part of the NHS CRS. We want
to enquire about their experiences of identifying these systems and setting them to work,
and to study the consequences (actual and projected) of the new electronic health record on
the safety and quality of care provided. We consider care pathways as a useful platform to
evaluate the transformational change that CRS may bring across different NHS settings. To
this aim, we will focus on stroke pathways, as a particularly relevant exemplar for the
analysis of NHS CRS used for coordination of care. We are also interested in assessing the
cost to Trusts of implementation.
To ensure we develop a rounded understanding of the issues relating to implementation of
NHS CRS in particular Trusts, our researchers expect to undertake anonymised interviews
with approximately six healthcare professionals (including doctors, nurses and allied
healthcare professionals) and six other hospital-based administrative, IT and managerial
staff. We will seek some patient input to the study depending on the situation in a particular
Trust. When appropriate we will wish to interview some persons more than once so as to
capture the changing situation. The project has also developed a survey instrument the
Clinical Computer Systems Survey (CLICS) to assess systems in use by clinical staffs
including doctors, nurses and pharmacists.
We are very aware of the pressurised hospital environment and will therefore make every
320
effort to minimise any disruption or time commitments for your staff, but taking part in this
study will take up a small amount of management, clinical and administrative staff’s time. We
will aim at keeping this at no more than two hours for any individual over the course of the
project.
We believe that there are a number of potential benefits for your Trust and staff participating
in this evaluation:
• Your Trust will have a detailed and real-time insight into how the new system is being
received on the ground and what steps might be undertaken to facilitate local
implementation.
• This research will allow you opportunities to feed back to NHS Connecting for Health
and the wider health policy community.
• The project team may also help to keep you up-to-date with the latest developments
in relation to the national implementation of the NHS Care Records Service.
This study has now been adopted by the UKCRN, further details of which are available at
http://public.ukcrn.org.uk/Search/Portfolio.aspx?titleAcro=&chiefInvStudyCoor
d=&isrctn=&UKCRNStudyID=7540&ResearchSummary=&SearchType=Any.
321
Appendix 10: Participant consent form
An evaluation of the adoption of the NHS Care Recor d in secondary care HEALTHCARE STAFF INTERVIEW CONSENT FORM
Please tick all the boxes and give this form back t o the receptionist. If you don’t feel
able to all the boxes, or if you change your mind a t any point, we will not include you in the research.
Tick
I have read the information sheet dated [please insert] and asked any questions I want, which were answered to my satisfaction (Please note that the information sheet gives the names of people you can contact to discuss the study)
I have been informed of the objectives of the study, my role within it, and the tasks I am expected to undertake
I understand that I will be participating in a study to investigate my perceptions and experiences of the NHS Care Records Service
I understand that I am free to withdraw from the study at any time and without giving a reason for withdrawing
I have been reassured that the procedures adopted by the researcher to ensure my anonymity as a participant will be maintained
I understand that the research team will agree to erase my contribution to the audiotape of the interview should I request this
I have been provided with the contact details of the research team and have details of the complaints procedure that I can use if I wish to
I am happy to be quoted (for example, when the research is published) so long as my name isn’t mentioned. [if not happy to be quoted, leave blank]
I agree to participate in the study
Name of participant (capitals): …….…….…………………………..……………………………………….
Signed: ………………………………………………….… Date: ………………..
I would prefer a face-to-face/telephone interview [please delete as appropriate] I agree to be contacted again for a follow-up inter view (please tick) Please return to: Insert name and contact details of relevant researcher
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Appendix 11: Sample list of documents collected
This list provides samples of the types and nature of the documents collected and analysed
during this evaluation.
Site A
Annual Report 2009-10
Annual Report 2008-9
Annual Report 2007-8
Business Plan 2008/9-2009/10
Business Plan 2009/10-2010/11
Management Structure Chart Document
AHSC Vision Document
CQC Performance Rating Summary
PALS Information Leaflet
Declaration of Compliance Document
Quality Accounts 2009-10
Consultation on Foundation Trust Application
Response to Foundation Trust Application
Board Meeting Minutes Feb. 2009
Board Meeting Minutes April 2009
Board Meeting Minutes June 2009
Annual General Meeting July 2009
Board Meeting Minutes Nov. 2009
Board Meeting Minutes Feb. 2010
Board Meeting Minutes April 2010
Board Meeting Minutes Sept. 2010
Board Meeting Minutes Jan. 2011
Trust News (360 Degrees) Jan. 2011
Trust News (360 Degrees) Jan. 2010
Site B
Deployment History Timeline
Electronic Patient Record Next Stage Business Case
Lessons Learnt Document
Lorenzo Newsletter
Pathology Catalogue
Project Initiation Document – Lorenzo R2
Site B Project Initiation Document (PID)
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Site B Trust Electronic Patient Record Next Stage Business Case Board March 09
Site C
Site C EA Risks 2008-06-18
Site C Version Of Local Cost Reporting Tool
Business Continuity Plan 180309 - Revised V03
EPR CAG Tor (Electronic Patient Record Clinical Advisory Group Terms Of Reference) March
2010 V1.1
GD CAG (Going Digital Clinical Advisory Group) Meeting Notes 2010 11 05
Lessons Learned Report
Local Cost Reporting Tool
Local Safety Agreement Milestone Sign-Off Recommendation For Deployment Go-Live ATP
Lorenzo Release 1 Clinical Documentation Project
Minutes – Project Board – 04.07.08
Minutes – Project Board – 14.05.09
Minutes – Project Board – 17.04.08
Minutes – Project Board – 17.09.08
Minutes – Project Board – 17.12.08
Minutes – Project Board – 20.03.09
Minutes – Project Board – 20.08.08
Minutes – Project Board – 20.11.08
Minutes – Project Board – 21.02.08
Minutes – Project Board – 22.05.08
Minutes – Project Board – 23.01.09
Minutes – Project Board – 25.03.08
Minutes – Project Board – 26.02.09
Minutes – Project Board – 26.03.09
Project Initiation Document – Lorenzo R1
SHA NIMM (National Infrastructure Maturity Model)
Y&H_14122010
Site D
CRS Action Log v0-3.xls
Benefits Review Plan v0.3 Draft.doc
Returning to BAUv0-3.doc
CER201000114 UK Roadmap Placemat - CCN3
CRS Phase 1 Audit Final Report
Weekly Service Management Dashboard
Costs summary
324
CRS Board minutes
CRS Finances
CRS Performance Test
Daily Performance Report
Divisional Training Stats
CRS Communication Plan
User Guides
CRS Highlight report
Report Milestones
Site E
070305-Lessons Learned
Actions Lessons Learnt
Activity And Finance Report
Appendix 2_2007.18 Trust Resource Requirements
Appendix 2_Training Plan V2
Appendix 4_Actions Lessons Learnt
Appendix B_Activity And Finance Report
Appendix B1_Timing Of The Care Records Service
Appendix C_Action List Lessons Learnt 14_01_08
Appendix F_CRS Financial Report March 2007
Benefit Paper_Nov07
Benefit Realisation Strategy _Nov07
Benefit Register V1.0
Benefit Register_Dec07
Benefits Paper And Register
Benefits Realisation Strategy
Benefits Strategy Approach (Benefit Realisation Strategy)
Business Continuity And Cutover Status
Business Continuity Plan
Business Transformation Report
Cerner Advisory Group Meetings: Agenda And Notes.
Cerner Foundation Reports And Feedbacks
Cerner Gold Meetings: Agenda And Notes
Champion Users Reports
Change Management Strategy
Clinical Engagement Strategy
Clinical Improvement Workplan
Clinical Workshop Updates
325
Clinical Workstream Overview
Correspondences With Users For Feedback And Recommendation
CR1_APR_0102 [name] 2007 18 Upgrade
CRS Communications Strategy
CRS Deployment High Risks & Issues
CRS Expenditure Report
CRS Expenditure Report Month 12 2007-8
CRS Expenditure Report Month 8 2007-8
CRS Expenditure Report Oct 2007 (Final)
CRS Financial Report
CRS Full Risk Register
CRS Interface Recovery Plan
CRS Key Dates Mar 07
CRS Key Dates Report
CRS Programme Board Meetings: Agenda And Notes
CRS Programme Review Meetings: Agenda And Notes
CRS Project Framework
CRS Project Organisation
CRS UK-User Group Presentations
CRS Workstream Meetings
Floorwalking Plans
Lessons Learned Presentations
Project Plan Reports
Project Status Report At Various Stages
Resources Assessment Reports
CRS Training Approach
Risk Assessments And Risk Issues
Service Management Status Updates
Shortcut To CRS Expenditure Report
Terms Of References Board
Timing Of CRS
Training Plans
Training Update 170707
Training Update Aug07
Various Presentations For Programme Update For Different Groups Of Participants
Site G
Trust Business Plan 2010 report RiO London – roadmap
Quality Account 2009/10 & Priorities 2010/11 Report
326
Update on the RiO v5 Implementation, 2009 Report
Annual Report 2009-10
Annual Report 2008-9
Policy document: Health Records
Policy document: Information Governance
Policy document: Risk Management
Operations Board Minutes 2010
RiO Mental Health Solution Document
RiO-CCN3 London Document
RiO London Roadmap
Site H
090210 NLOP HR Subgroup Minutes
090317 NLOP HR Subgroup Minutes
090421 NLOP HR Subgroup Minutes
Agenda July 09 Lorenzo 1 V0.2
Evaluation Interim Report
IMT Leads Minutes 090112 V0.2
IMT Leads Minutes 090317 V0.1
IMT Leads Minutes 090421 V0.2
LRC Deployment Units
NLOP Board Briefing Paper (Agenda Item 3)
NLOP Board Briefing Paper (Agenda Item 4)
NLOP Board Briefing Paper (Agenda Item 5)
NLOP Board Briefing Paper (Agenda Item 5) Review
NLOP Board Briefing Paper (Agenda Item 5) Training
NLOP Board Briefing Paper (Agenda Item 6)
NLOP Board Briefing Paper (Agenda Item 6) Finance Subgroup
NLOP Board Briefing Paper (Agenda Item 6) Paper
NLOP Board Briefing Paper (Agenda Item 6) Smoothing Changes
NLOP Board Briefing Paper (Agenda Item 7) Chunk Projects
NLOP Board Briefing Paper (Agenda Item 7) Host Organisation
NLOP Board Briefing Paper (Agenda Item 7) Interim Extension
NLOP Board Briefing Paper (Agenda Item 7) LIG Monies Paper
NLOP Board Briefing Paper (Impact Of Delay Paper)
NLOP Board Briefing Paper (SHA Briefing Paper)
NLOP Board Minutes 071008 V0.3
NLOP Board Minutes 090220 V0.3
NLOP Board Minutes 090625 V0.3
327
NLOP Board Minutes 111208 V0.2
NLOP Board Minutes 120608 V0.1
NLOP Board Minutes 200808 V0.3
NLOP Central Team Transition V0.2
NLOP Change Advisory Board
NLOP Cost – Benefit – Risk Paper
NLOP Finance Subgroup Minutes 20090107
NLOP Finance Subgroup Minutes 20090217
NLOP Finance Subgroup Minutes 20090521
NLOP Phase 1 Assumption
NLOP Resourcing
NLOP Workshop All A Feedback
NLOP Workshop B Trust Overlap
NLOP Workshop C Trust Benefits
NLOP Workshop D Timescales And Smoothing
Pro And Con’s Of Going It Alone
Project Status Reports X 2
Site H Project Initiation Document (PID)
Site M
090727 Highlight & Transformation Report
Action Logs X1
Benefit Plan By BT, Oct 10 X 1
Board Agenda 28 Jul 09
Business As Usual X 1
Annual Report
CCN3 X 2
Consultancy Reports X 3
CRS Board Docs X 22
CRS Update X 13
Enc 4 High Level Plan5 (Go-Live Schedule)
Enc 5 Rio Risk Register
FBC Benefit Update 081223
Finance X 2
General Documents X 12
Lessons Learnt
Minutes Of 26 March 2009 Meeting Of The Foundation Trust
Minutes Of [name] Rio Go-Live Meeting May 6
Performance X 5
328
Progress Reports X 16
Project Initiation Document V1.2 191108
Rio Board Meetings (Board Agenda 22 Oct 09)
Rio Board Meetings (Board Agenda 28 July 09)
Rio Board Meetings (Board Agenda 4 Dec 09)
Rio Board Meetings (Board Agenda 4 Sep 09)
Rio Compliance Status Reports (PER-PD3-0051)
Rio Compliance Status Reports (Stage 3b)
Rio Full Business Case (V1.0.5 Draft)
Rio Issues Register (V 2.0 CI)
Rio Risk Register (V2.4 CI)
TB Header X 13
User Guides X 22
Visio-[name]High Level Plan 7 (Go-Live Schedule)
Work Stream X 13
As Is Process Map1_Vfinal
As Is Process Map2_Vfinal
As Is Process Map3_V0.4final
To Be Process Map_V1.4
Rio Eprescribing Benefits Baseline Plan_Vfinal
Rio Eprescribing Pilot Introduction_Final
Rio_Triage_Webit_V1
E-Prescribing Demo Agenda 19072010
Frequently Asked Questions 1.3
Rio Eprescribing Pilot_PID_Final
Rio Eprescribing Outpatient Agenda_V5.4-1.0
Rio Eprescribing Pilot_Formal Participation Letter
Rio Eprescribing Pilot Training Manuals 1 and 2
Rio Eprescribing Pilot Training_Agenda
Rio Eprescribing Pilot Baseline Reports_V1.0
Site P
Benefits Mapping_Ver0.6
Is CRS Efficient?
Mappings Summary For Evaluation
Relative Importance And Complexity
Trust Information Leaflet On Hospital Redevelopment
Meeting Summary Of Innovation Workshop 31st March 2009
Our 'To Do' List For 2009/10
329
Measuring Patient Safety - Powerpoint Presentation
Site Q
Site Q Deployment Verification Reports X 2
Site Q Lessons Learnt Report
Site Q Project Initiation Document (PID)
Site R
BCP Plan For Cutover
Business Continuity Plan For Downtime Procedures
CERNER Installation And SEMAHELIX Downtime [CONFIDENTIAL]
Change Report For PID
Clinical Risk Of Untimely Haste In “Go-Live” Of Care Records Systems (CRS) In The NHS
Connecting For Health Programme [CONFIDENTIAL]
Lessons Learned Report
NHS Governance And Cerner Millennium R0 [CONFIDENTIAL]
Nursing Handover Notes On Semahelix [CONFIDENTIAL]
PID
Risk Register
Some thinking about CRS and a way ahead for the NHS CRS Project [CONFIDENTIAL]
Site X
Site Map Of [name]
Lorenzo Regional Care Information Booklet (Includes Benefits DVD)
Lorenzo Regional Care Information Pack - Short Document, Coloured Printout
Lorenzo Regional Care Information Pack - Long Document, Product Details And Deployment
Process
Training Flyer Advertising Courses
It Skills Self-Assessment Form
It Skills Information Document
Benefits Of Lorenzo
[name] Pathology Training Approach
Information Pack Lorenzo
The Lorenzo System Starter Pack (Powerpoint Presentation)
[Clinic name] Clinical Documentation Go-Live Starter Pack
Powerpoint Presentation Regarding Business Change From LSP
News Article From British Journal Of Healthcare Computing & Information Management
Email From Programme Manager To Project Board
Supporting Information For Locally Produced Discharge Summary System.
330
Notes From Medical Records Department
Other Sources
The Information Commissioner’s Office: The NHS Care Record Guarantee
The King’s Fund; Windmill 2009: NHS Response To The Financial Storm
Impact Study: Report On The Socio-Economic Impact Of Interoperable Electronic Health
Record (EHR) And Eprescribing Systems In Europe And Beyond
London Programme For IT: Connecting Care Across The Capital, Benefits Statement 2007/
2008.
Hayes, G, 2009: Independent Review Of NHS And Social Care IT.
Copy Of Local CRS Business Case VFM Tool.Xls
NHS CFH NHS IM&T Investment Survey 2008.Pdf
The National Programme For IT In The NHS: Progress Since 2006.
Several Sets of Minutes from our meetings with Connecting for Health
Several sets of press documents
331
Appendix 12: Survey instrument: Work-Packages 1-3 C LICS
332
333
334
335
Appendix 13: Information sheet for CLICS
CLICS • Clinical Computer Systems Survey
A survey for all clinical staff across different NH S services
Brief summary and research protocol v. 4 Feb. 2010 - Revised draft document prepared at LSE. Internal document, not for publication. All comments to: Valentina Lichtner - [email protected]
This survey is part of a wider project investigating the adoption of the NHS Care Records Service in England. More information on the project can be found at http://www.nhs-crs.org.uk/ Introduction
Clinical Computer Systems Survey (CLICS) was developed by the London School of
Economics in collaboration with the University of Edinburgh, the School of Pharmacy, the
University of Nottingham and Imperial College, in the context of the research project An
Independent Evaluation of the Adoption of the NHS Care Records Service in Secondary
Care (NHS CFHEP 005 project).
CLICS is a survey tool to investigate the use and usability of electronic patient records and
related clinical systems, and the user experience with these, including attitudes and opinions.
The survey design is based on a sociotechnical view of the adoption of clinical information
systems. This view is expressed in four constructs: 'computerisation', 'usability and safety', 'clinical
and organisational management' and 'patient journey' (see Appendix 1).
CLICS also reflects the ambitions for IT in the UK, specifically the 'Clinical 5' as described in
the Health Informatics Review Report, July 2008 - the key elements of a strategic IT system
in clinical context:
• A Patient Administration System (PAS) with integration with other systems and sophisticated
reporting;
• Order Communications and Diagnostics Reporting (including all pathology and radiology tests
and tests ordered in primary care);
• Letters with coding (discharge summaries, clinic and Accident and Emergency letters);
• Scheduling (for beds, tests, theatres etc.);
• e-Prescribing (including 'To Take Out' (TTO) medicines). (Health Informatics Review Report,
July 2008, p26)
336
While the Health Informatics Review recommends the Clinical 5 for secondary care, we
found that they can also be applicable to other NHS services, such as Mental Health
community services.
Clinical work is often based on inter-disciplinary teams and clinical systems are used by a
variety of roles. Thus, CLICS has been explicitly designed as a survey that can be answered
by doctors, nurses and pharmacists, and possibly other members of the clinical team.
Finally, the questionnaire was designed to be short and not too time consuming: it prints on
to 4 sides of an A4 paper, making it a manageable paper version, though an online delivery it
is envisaged in most settings, via a url link circulated by email.
CLICS is distributed across different NHS Trusts to enable a comparison across contexts.
Scope of this survey
CLICS is targeted at clinicians in different NHS Trusts: primarily doctors, nurses and
pharmacists, in both acute and community settings.
Method for distribution within each setting
The following is a brief protocol for distribution of CLICS within the different Trusts:
• The launch and distribution within the setting is to be agreed with the Trust/NHS
service site.
• A customised online and PDF version will be created for each Trust participating in
the survey. Each Trust will be assigned its own different web address (URL) to
access the online version of the survey. A demo version is available online at:
https://www.survey.bris.ac.uk/lsewebsite/clics-demo/
• The survey can be completed online and/or by printing the PDF file attached to the
email (retuned by post); if appropriate to the local context, CLICS questionnaire on
paper could also be distributed and collected on site.
• The online version will remain available for 3 weeks from launch. A reminder email
will be sent on week 2.
• Participation in the survey is anonymous and the survey should take no more than 10
minutes to complete.
• Results in aggregate form will be shared with the participating organisation. The survey
captures the richness of clinical IT used in the Trust, from computerisation, to usability,
337
safety, management and patient journey. Both qualitative and quantitative results will be
included in the report to the participating organisations.
• No participating Trust will be identifiable in overall comparative analysis.
Incentive:
Participation to the survey qualifies for UKCRN accruals. More information can be found on
http://public.ukcrn.org.uk/Search/StudyDetail.aspx?StudyID=7958
References
Department of Health (2008) Health Informatics Review Report - Ref. 10104.
http://www.dh.gov.uk/en/Publicationsandstatistics/Publications/PublicationsPolicyAndGuidance/
DH_086073
338
Appendix 14: The 12 core principles of the NHS Care Record Guarantee
1. “When we receive a request from you in writing, we must normally give you access to
everything we have recorded about you. We may not give you confidential information
about other people, or information that a healthcare professional considers likely to
cause serious harm to the physical or mental health of you or someone else. This
applies to paper and electronic records. However, if you ask us to, we will let other
people see health records about you. Wherever possible, we will make your health
records available to you free of charge or at a minimum charge, as allowed by law. We
will provide other ways for you to apply to see your records if you cannot do so in writing.
We will provide information in a format that is accessible to you (for example, in large
type if you are partially sighted).
2. When we provide healthcare, we will share your record with the people providing care or
checking its quality (unless you have asked that we limit how we share your record).
Everyone looking at your record, whether on paper or computer, must keep the
information confidential. We will aim to share only as much information as people need
to know to play their part in your healthcare.
3. We will not share health information that identifies you (particularly with other
government agencies) for any reason other than providing your care, unless:
• you ask us to do so;
• we ask and you give us specific permission;
• we have to do this by law;
• we have special permission for health or research purposes; or
• we have special permission because the public good is thought to be of greater
importance than your confidentiality.
If we share information without your permission, we will make sure that we keep to the
Data Protection Act 1998, the NHS confidentiality code of practice and other national
guidelines on best practice. There is more information about existing guidelines at:
www.dh.gov.uk/en/Managingyourorganisation/Informationpolicy/Patientconfidentialityand
caldicottguardians/index.htm
4. Under current law, no-one else can make decisions on your behalf, about sharing health
information that identifies you. At the moment, the only exceptions to this are parents or
legal guardians, or people with powers under mental health or other law. You can
appoint someone to have a lasting power of attorney to make decisions for you if you
lose the ability to make decisions for yourself. You can decide what rights that person
has in making decisions about your care record. If you do not appoint anyone, a senior
339
healthcare professional involved in your care may consider it to be in your best interests
to share information. This judgment should take account of the views of your relatives
and carers, and any views you have already recorded. For medical research or other
purposes, the Ethics and Confidentiality Committee of the National Information
Governance Board for Health and Social Care can give special permission to share any
health information that could identify you.
5. Sometimes your healthcare will be provided by members of a care team, which might
include people from other organisations such as social services or education. We will tell
you if this is the case. When it could be best for your care for your health information to
be shared with organisations outside the NHS, we will agree this with you beforehand. If
you don't agree, we will discuss with you the possible effect this may have on your care
and alternatives available to you.
6. Usually you can choose to limit how we share the information in your care records which
identifies you. In helping you decide, we will discuss with you how this may affect our
ability to provide you with care or treatment, and any alternatives available to you.
7. We will deal fairly and efficiently with your questions, concerns and complaints about
how we use information about you. All Trusts have a Patient Advice and Liaison Service
(PALS) which can answer questions, point people towards sources of advice and
support, and advise on how to make a complaint. We will have a clear complaints
procedure. We will use what we learn from your concerns and complaints to improve
services.
8. We will take appropriate steps to make sure information about you is accurate. You will
be given opportunities to check records about you and point out any mistakes. We will
normally correct factual mistakes. If you are not happy with an opinion or comment that
has been recorded, we will add your comments to the record. If you feel you are
suffering distress or harm as a result of information currently held in your record, you can
apply to have the information amended or deleted.
9. We will make sure, through contract terms and staff training, that everyone who works in
or on behalf of the NHS understands their duty of confidentiality, what it means in
practice and how it applies to all parts of their work. Organisations under contract to the
NHS must follow the same policies and use the same controls as the NHS does. We will
enforce this duty at all times.
10. We will take appropriate steps to make sure we hold records about you – both paper and
electronic – securely and only make them available to people who have a right to see
them.
11. We will keep a record of everyone who accesses the electronic information the NHS
Care Records Service holds about your diagnosis, care and treatment. You will be able
340
to ask for a list of everyone who has accessed records that identify you, and when they
did so. There may be times when someone will need to look at information about you
without having been given permission to do so beforehand. This may be justifiable, for
example, if you need emergency care. We will tell you if the action cannot be justified.
12. If we find that someone has deliberately accessed records about you without permission
or good reason, we will take action. This can include disciplinary action, ending a
contract, firing an employee or bringing criminal charges. We will tell you if this happens.”
Quoted from (130)
341
Appendix 15: Interview topic guide: Work-Package 4
Interview Schedule
Informed about the purpose of the interview; Are you happy for the interview to be recorded?
Is there anything you’d like to ask me before we begin the interview?
1. To start with, it would helpful if you could tell me a little bit about yourself. What is your
particular role?
2. Can you briefly explain what is currently happening around the implementation of
(Lorenzo, Millennium, RiO)?
3. Why did your Trust choose to become an early adopter?
4. Regarding the implementation, what is the timeline?
5. What would you say have been the costs so far?
Prompts:
• Hardware; Software; Data Migration
• Training; Personnel; Estate;
• Networking; Interfacing; Other costs.
6. What would you say have been the benefits so far (if any)?
Prompts:
• Perceived ‘current’ benefits
• Perceived ‘future’ benefits
• Disbenefits?
7. What does the functionality currently allow you to do?
8. What are the reasons for not achieving the benefits?
9. Any benefits measurable?
10. What is the single, most important piece of advice you could give to future
implementation sites for them to benefit from what you have learned from your experiences?
11. Is there anything we have not discussed that you would like to bring to my attention?
12. Any documents / information that were relevant to our discussion and that you think
would be useful for our study?
13. If for any reason, I need to contact you again, would you mind?
Appendix 16: Minimum Data Set Cost Framework Work-P ackage 4
INFRASTRUCTUR
E
Infrastructure refers to key IT architecture required to implement EHR.
E.g. Printers, PCs, scanners.
PRIOR TO
IMPLEMENTATION
(Readiness preparation)
START UP COSTS RECURRING COSTS
Domains Categories Units Specification Units Amount
(£) Units
Amount
(£)
Hardware Standard Personal Computers
Computer on Wheels
Wall-mounted computers
Keyboards (Infection Control)
Tablet PCs
Printers
Wrist-band Printers
Paper Printers
Label Printers (Mobile)
Label Printers (Fixed)
Scanners
343
SmartCards & peripherals
Servers
Domain control (log in)
Printers
Software application
Power source
Power sockets (per PC)
Data sockets (per PC)
Cabling
Switches (network electronics)
Batteries, docking
Maintenance and
support (Hardware)
(see personnel)
Software Additional applications
Project management software
Change management software
Reporting software
e-learning application
Data quality dashboard
Discharge summary application
Business continuity application
Corporate dashboard
Integration engine
344
Training database
Data warehouse (enhancement)
Operating system (e.g. windows)
Disaster recovery system
Service desk system
Anti-virus
Licenses
Machine licenses (per computer)
Intermediate systems
Maintenance and
support (Software)
(see personnel)
PERSONNEL
Personnel are all staff costs related to EHR and implementation of EHR, including training.
E.g. Project management, floorwalkers, IT trainers.
PRIOR TO START UP COSTS RECURRING COSTS
345
IMPLEMENTATION
Domains or Roles Examples of Roles Units Band /
Amount (£) Units
Band /
Amount (£) Units
Band /
Amount (£)
Project management
team Project Executive
Programme Lead / Manager
Senior Project Lead / Manager
Project Lead / Manager
Project Administrators
Finance Lead
Change management
team Change Lead / Manager
Organisation Development Lead /
Manager
Business Change Analysts
Benefit Lead
Training team Training Lead / Manager
Trainers
Floorwalkers
e-learning developer
ETD Lead
Staff backfill
Doctors
346
Nurses
Admin
Data migration &
Integration team Data Migration Manager
Data Migration / Entry Group (Coders,
Keyers)
Data Quality/Assurance lead
Interface expert
Configuration & testing
team Build manager
Product specialists
Software developers
EPR advisors
Test manager
Test script manager
Testers
Quick test/Load runner analyst
IT service
management/operations
team Service-desk Manager
Service-desk operators
IT engineers
347
Application support
Business transformation
team Communications Lead / Manager
Issues Management Lead / Manager
Business Continuity Lead / Manager
Risk Lead / Manager
Cutover Manager
Caldicott Guardian
Registration authority
team RA Lead / Manager
Clinical team Medical Director
Clinical Lead
Pathology Lead
Radiology Lead
Pharmacy Lead
Nursing Lead
Champion users
Administrative team Back Office Manager
Back Office Staff
348
Overtime (e.g. Rehearsal)
ESTATES
Estates costs are costs incurred while installing an appropriate environment for EHR.
E.g. Wi-Fi or network wiring, server rooms.
PRIOR TO
IMPLEMENTATION START UP COSTS RECURRING COSTS
Domains Categories Units Band /
Amount (£) Units
Band /
Amount (£) Units
Band /
Amount (£)
Project management
estate Project management room
Project management room furniture /
fittings
Desks
PCs
Printers
Wall-mounts
Training estate Training rooms (Inc. lecturer theatres,
349
training buses)
Training rooms furniture / fittings
Desks
PCs
Printers
Wall-mounts
Data
migration/integration
estate
Data migration / integration room
Furniture / fittings
Desks
PCs
Printers
Wall-mounts
Configuration / Testing
estate
Configuration / testing room
Furniture / fittings
Desks
PCs
Printers
Wall-mounts
350
IT service
management/operations
estate
Data migration / integration room
Service desk furniture / fittings
Desks
PCs
Printers
Wall-mounts
Change management /
Business transformation
estate
Change management / business
transformation room
Furniture / fittings
Desks
PCs
Printers
Wall-mounts
Clinical / administrative
estate
Clinical / administrative room
Furniture / fittings
Desks
PCs
Printers
351
Wall-mounts
Storage space Server storage space
Wi-Fi network Secure wireless network installation
Cabling
Router
VPN Connectivity
Wards Furniture / fittings
Nursing stations (Refitted)
Desks
OTHER COSTS & MATERIAL
Other materiel costs are costs incurred for materials-use during implementation
E.g. Training material, consumables.
PRIOR TO
IMPLEMENTATION START UP COSTS RECURRING COSTS
Domains Categories Units Specification Units Band /
Amount (£) Units
Band /
Amount (£)
352
Data migration Server
(Inc. data
cleansing)
Interfacing
Rehearsal (go-
live) (See personnel)
Consumables Catering (incl. staff)
Toilet consumables
Training materials Printed materials
Manuals
Fan folds
Other training Transport
Accommodation
Routine service
provision
Cleaning
Miscellaneous Security
Parking
Appendix 17: Information sheet for Work-Package 5: Case note availability study
NHS CFHEP 005 EVALUATION OF THE ADOPTION OF THE
NHS CARE RECORDS SERVICE IN SECONDARY CARE
The availability and completeness of Outpatient Cli nical Records
Summary
The overall aim of WP5 is to investigate whether the introduction of the NHS CRS in England results in an improvement in availability of clinical records and clinical test results in secondary care outpatient settings. This study aims to assess outpatient case notes working with clinicians and clinic staff in a variety of outpatient settings.
Availability of clinical information at outpatient clinics All NHS Trusts are required to monitor the availability and quality of medical records as this is one of the NHSLA standards9. Standards for documentation in medical records set by the Royal Colleges are used as the basis for audit of the structure and quality of documentation in medical notes.
In 1995 the Audit Commission published a study of hospital health records based on a survey of 225 respondents from 40 hospital Trusts10. This study “Setting the Records Straight” reported major problems including difficulties in retrieving records for consultation, poor quality of record-keeping within the casenote folder and poor facilities for storage of records. This was at a time when many Trusts did not have any form of electronic case note tracking. The Audit Commission made several recommendations and set a benchmark of 95 per cent availability of casenotes at clinics. At that time as many as one in six sets of casenotes were not available at the start of clinic. An update to the 1995 study was published in 199911. Tables 1 and 2 below summarises the key findings of both studies.
Table 1 Availability of Casenotes at Out Patient clinics
1995 1999 AVAILABILITY OF CASENOTES AT START OF OUTPATIENT CLINICS Benchmark of 95% 75% met the benchmark 84% met the benchmark
Clinics achieving 99% or better for
availability of casenotes at start of clinic
18% 50%
ELECTRONIC CASE NOTE TRACKING
Implemented in only a few
Trusts
62% of Trusts used
casenote tracking; a further
18% were planning to
introduce it in the next 12
months
A similar survey of 49 hospitals published in 2008 reported that out of over 2 million outpatient appointments, 54,000 were conducted without the clinician having access to the
9 NHSLA Risk Management Standards for Acute Trusts Primary Care Trusts and Independent Sector
Providers of NHS Care 2009/2010 NHS Litigation Authority 10 Setting the record straight A study of hospital medical records. Audit Commission, November
1995. 11 Setting the record straight A review of progress in health records services. Audit Commission
Update, November 1999.
354
patient’s full record12 . Non-availability was self-reported by the organisations surveyed and ranged 5-19%.
Table 2 Time taken to retrieve case notes
TIME TAKE TO RETRIEVE CASE NOTES 1995 % casenotes % of time taken
to find notes
Where case notes are when required for clinic
Filed in the library 64% 30%
Elsewhere in Trust but recorded 31% 61%
Not traced 5% 9%
Aims/Objectives
The overall aim of our study is to investigate whether the introduction of the NHS CRS in England results in an improvement in availability of clinical records and clinical test results in secondary care outpatient settings. To undertake this study we will work with a minimum of six Trusts across England who use paper and/or electronic records.
The key objectives include measuring:
� The proportion of outpatient encounters associated with completely missing records;
� The proportion of outpatient encounters associated with partly missing records.
� The frequency with which particular elements needed by the clinician were missing.
� The overall assessment of the completeness of the clinical records
Method 1) An observational study in outpatient clinics. The Trust will receive an initial visit from a
researcher to plan the work with a staff member from the Trust. This visit will identify which clinics to be used, will talk to the senior clinicians involved, the senior nurse and, if necessary, will speak to the appropriate medical records staff and clinic staff.
2) The observational study will take up to three days. During those three days up to five or six clinics will be surveyed. The researcher will then visit the Trust again an agreed number of weeks later to undertake a similar survey again for three days. We are looking to use general medicine and general surgery clinics within this assessment along with some speciality clinics. We are looking at clinics using either or both paper and electronic records.
3) During the assessment healthcare professionals will be asked to report on the availability of the medical records at the time of consultation.
4) In addition there will be survey of the clinic managers/ administrators to gain valuable background information for each clinic and to establish pre-existing levels of computerised records.
5) The researcher will report back to the Trust on the results of the data analysis and the survey undertaken.
12 Gainsbury S. (2008) Missing: The notes of more than a million outpatients. Health Services Journal, 22 May p5
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Appendix 18: Interview topic guide for Work-Package 5: Case note availability study:
First interview
An Independent Evaluation of adoption of the NHS Ca re Records Service (NHS CRS)
in the NHS
INTERVIEW GUIDE FOR OPD AND MEDICAL RECORDS STAFF
To provide you with some background to this evaluation: We are a multidisciplinary team
working across several universities evaluating the adoption of the NHS Care Records
Service in secondary care in England. There are 5 Work Packages and I am working on
Work Package 5.
Anonymity and confidentiality is important and I want to assure you that all of this interview
data will be anonymised and treated in strict confidence. It will not be possible to identify you
in any reports or publications arising from the evaluation research.
We would like your honest views, whether they are positive or negative. If there is a question
you feel you cannot answer, we can skip that question and similarly if there is anything that
you feel that I have missed out and you would like to comment on then please do so.
Is there anything you’d like to ask me before we begin the interview?
To start with, it would helpful if you could tell me briefly a little bit about yourself. How long
have you worked at [insert Trust/hospital name] and what is your current role?
[Probe - Name / How long worked in that position / How long have been in NHS / What is
your background]
Can you tell me about the process in Outpatients / Medical Records for collecting the
medical notes and getting them to the clinics?
[Probe – what role do you play?]
How well does that process work in your view? Are there any problems?
[Probe – request examples of problems encountered]
Are there any missing items at all? / missing medical notes?
[Probe – request examples]
How do you deal with the problem of missing items?
356
[Probe – request examples of dealing with the problems]
How would you view the relationship between the Medical Records department and
Outpatients?
[Probe - what challenges arise in working together?]
How can that process be improved in your opinion?
Some functions of the new NHS CRS will be implemented at some time. Are you looking
forward to it?
[Probe – acceptance of change, knowledge of developments, explore attitudes]
How do you anticipate your role will change when that happens?
[Probe: specific aspects of job clearer/easier/faster/safer and e.g., timeliness/helpfulness]
Does this affect your attitude to your own work?
Thinking beyond your own work role, what hospital-wide changes do you believe will
result/are resulting/have resulted from the new system/s
• in the ways in which the hospital staff’s work is organised?
• in the ways in which patients’ care is delivered?
• in the safety of patient care? [Probe]
• in the quality of patient care? [Probe]
What kind of other electronic systems do you currently have in outpatients?
[e.g. Results Reporting, PACS]
Overall, how would you describe your attitude towards the goal of a national, (or even a
local) electronic patient record service?
What are your thoughts on the most appropriate way to work towards that goal?
What do you believe would help to facilitate the roll-out of the CRS nationwide the most?
What do you believe is the biggest barrier to a nationwide roll-out of the CRS?
357
Is there anything we have not discussed that you would like to bring to the attention of the
evaluation team?
How computer literate do you think you are?
Any other issues you would like to comment on?
Thank you for taking part in this interview. We greatly appreciate your giving your time. Do
you have any questions for me before we close?
358
Appendix 19: Interview topic guide for Work-Package 5: Case note availability study:
Return Interview
INTERVIEW GUIDE FOR OPD AND MEDICAL RECORDS STAFF – POST IMPLEMENTATION
Thank you for agreeing to be interviewed
I would like to assure you (once again) that all data supplied in this interview will be
anonymised and treated in strict confidence. It will not be possible to identify you in any
reports or publications arising from the evaluation research.
We would like your honest views, whether they are positive or negative. If there is a question
you feel you cannot answer, we can skip that question and similarly if there is anything that
you feel that I have missed out and you would like to comment on then please do so.
Is there anything you’d like to ask me before we begin the interview?
To start with can you tell me your work title and where you are based?
[Probe-Name? / How long worked in that position? / How long have been in NHS? / What is
your background?]
Last time we spoke about the processes of medical notes within the OPD. Have there been
any changes as a result of implementing the NHS CRS system [..] since then? Can you tell
me how that has affected you and your work?
[Probe – what it means for them, has it changed any ways of working in the OPD / Medical
Records.]
What positive changes, if any, are you experiencing? / Do you anticipate your own role
changing as a result of the introduction of the new system/s?
[Probe: specific aspects of job clearer/easier/faster/safer?]
What negative changes, if any, are you experiencing? / Do you anticipate changes in your
own role as a result of the introduction of the new system/s?
[Probe: specific aspects less clear, more difficult/slower/less safe?]
Has this increased the number of missing items in the medical notes or are there fewer items
missing?
What day-to-day support was provided during the changeover period?
359
What day-to-day support is currently available now?
[Probe: e.g., timeliness/helpfulness]
Were you involved in any away with the development of the system?
Have the patients made any comment about the new system?
[Probe – whether positive or negative or indifferent]
What kind of training did you receive? How useful was it?
[Probe – whether trainer came down to the department, floorwalking, quality of training,
knowledge of trainers ]
What do you do if you have a problem with the system now?, Who do you contact?
How is all this affecting your attitude to your own work?
[Probe - improved way of working / more stress]
Have the changes affected your working relationships with colleagues?
Have the changes affected your working relationships with Medical Records / Outpatients?
[Probe – better relationship as easier to get the notes or less need for the notes, or worse
relationship as more time taken to get the notes]
Looking back, how would you change the way the system was implemented?
[Probe - What would you have done differently, if anything?]
Are there any other changes that have happened since I was previously here?
[Probe – management changes, policy changes, other technological changes etc]
Any other issues you would like to comment on?
Thank you for taking part in this interview. We greatly appreciate your giving your time. Do
you have any questions for me before we close?
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Appendix 20: Survey instrument: Work-Package 5 case note availability data sheet
An Independent Evaluation of adoption of the NHS Ca re Records Service (NHS CRS)
THIS DOCUMENT IS TO BE PINNED ON TOP OF THE PATIENT NOTES
1- Was all the information (notes, investigations, etc) you needed available
when the patient was seen? Yes No
If the answer to question above is yes, please stop here.
We thank you very much. Otherwise, and if the answer is no, please continue.
2- Is the patient new to this clinic? New Follow-up
3- Please indicate which parts of the records were unavailable:
3.1- The referral letter
3.2- Images (e.g. X-rays, MRI, etc.)
Please specify....................................................................................................
3.3- Monitoring results
e.g. 24 hrs blood pressure, 24 hrs heart monitoring, etc)
Please specify....................................................................................................
3.4- Lab Results (e.g. blood results.)
Please specify....................................................................................................
3.5- Reports (e.g ECG, rehabilitation, etc.)
Please specify....................................................................................................
3.6- Addressograph labels (stickers)
3.7- Complete medical notes ………………………………………………………………………
3.8 – Other: please specify ………………………………………………………………………..
4- Was the missing information obtained during the course of the clinic? Yes N
5- Did the lack of information availability result in any of the following consequences:
5.1- Delays to the consultation? Yes No Cancelled
5.1.1- If yes, by how long (please estimate delays in minutes)………………………………
5.2- Ordering another investigation? Yes No
5.3- Repeating consultation as a result? Yes No
5.4- Or any other decision that you made.
Unavail Not Availa
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Appendix 21: Work-Package 6: International EHR conf erence programme
This conference was held on 26th October 2010 at One Great George Street, Westminster,
London SW1P 3AA.
8.30 - 9.00 Registration & Coffee/Exhibition
9.00
THE NHS CARE RECORDS SERVICE: MAIN FINDINGS FROM NA TIONAL
EVALUATIONS
CHAIR:
Prof. Matthew Swindells, Chairman, British Computer Society (BCS Health)
SPEAKERS:
Prof. Trisha Greenhalgh, Principal Investigator, Summary Care Record
Prof. Aziz Sheikh, Principal Investigator, Detailed Care Record
10.30 Coffee & Exhibition
11.00
NATIONAL PERSPECTIVES
CHAIR:
Prof. Tony Avery, University of Nottingham
SPEAKERS:
Dr. Simon de Lusignan, St. George’s Hospital - University of London (NHS
England)
Dr. Martin Murphy, Welsh Assembly Government (NHS Wales)
Dr. Brian Robson, Medical Director, Quality Improvement Scotland (NHS
Scotland)
12.15 Lunch & Exhibition
1.00
THE STATE OF PLAY INTERNATIONALLY
CHAIR:
Dr. Sarah Crowe, University of Nottingham
SPEAKERS:
Prof. Denis Protti, University of Victoria (Canadian perspective)
Prof. David Bates, Harvard School of Public Health (U.S. perspective)
Dr. Karl Stroetmann, Empirica Communication & Technology (E.U. perspective)
2.30– 3.00
DEBATE: APPROACHES TO EHR DEVELOPMENT & IMPLEMENTAT ION
362
MODERATOR:
Prof. Denis Protti, University of Victoria
SPEAKERS:
Prof. Dipak Kalra, University College London (Top-down)
Prof. Ken Eason, Loughborough University; The Bayswater Institute (Bottom-
up)
3.00– 3.05 Poster Prize
3.05– 3.25 Coffee & Exhibition
3.25
PANEL DISCUSSION: SUCCESSFUL IMPLEMENTATION OF EHRs
CHAIR:
Prof. David Bates, Harvard School of Public Health
PANELISTS:
Prof. Chris Johnson, University of Glasgow
Prof. Jeremy Wyatt, Warwick University
Prof. Ken Eason, Loughborough University; The Bayswater Institute
Ms. Heather O’Brien, Director of Information Systems, Royal Free
Dr. Claudia Pagliari, University of Edinburgh
Dr. Josip Car, Imperial College London
4.25
INNOVATION, SHARING AND INFORMATION:
REDISCOVERING LOST VALUES
CHAIR:
Prof Aziz Sheikh, The University of Edinburgh
SPEAKER:
Prof. Aidan Halligan, Director of Education, University College London
Hospitals; Chief of Safety, Brighton & Sussex University Hospitals
5.00 CLOSE